0.1.24

* Fix IE11 for in bug in motor field

* minor fix

.gitignore

@@ -16,6 +16,7 @@ clients/win10/*.opendb
 clients/**/bin/**
 clients/**/obj/**
 clients/electron/projects
+libs/**/_locales/**
 
 videos/**
 

README.md

@@ -1,16 +1,17 @@
-# LEGO Mindstorms EV3 target for PXT
+# LEGO® MINDSTORMS® Education EV3 for Microsoft MakeCode
 
 [![Build Status](https://ci2.dot.net/buildStatus/icon?job=Private/pxt_project_rainbow/master/pxt-ev3_Push)](https://ci2.dot.net/job/Private/job/pxt_project_rainbow/job/master/job/pxt-ev3_Push/)
 
-This repo contains the editor target hosted at https://d541eec2-1e96-4b7b-a223-da9d01d0337a.pxt.io/
+This repo contains the editor target hosted at https://makecode.legoeducation.com
 
-Issue tracker: https://src.education.lego.com/groups/ev3-makecode
+LEGO Auth: https://src.education.lego.com/groups/ev3-makecode (use Google Authenticator)
+LEGO Chat: https://chat.internal.education.lego.com/make-code/channels/town-square
 
 ## Local Dev setup
 
 These instructions assume familiarity with dev tools and languages.
 
-* install Node.js 6+
+* install Node.js 8.9.4+
 * install Docker; make sure `docker` command is in your `PATH`
 * (optional) install [Visual Studio Code](https://code.visualstudio.com/)
 
@@ -57,12 +58,6 @@ cd libs/core
 pxt deploy
 ```
 
-### Hosted editor
-
-Currently hosted at:
-
-https://d541eec2-1e96-4b7b-a223-da9d01d0337a.pxt.io/
-
 ### Jenkins build
 https://ci2.dot.net/job/Private/job/pxt_project_rainbow/job/master/
 

cmds/cmds.ts

@@ -1,16 +1,11 @@
-/// <reference path="../node_modules/pxt-core/typings/globals/node/index.d.ts"/>
 /// <reference path="../node_modules/pxt-core/built/pxtlib.d.ts" />
 
 import * as fs from 'fs';
 
-require("./editor")
-
-declare namespace pxt.editor {
-    function deployCoreAsync(resp: pxtc.CompileResult, disconnect?: boolean): Promise<void>;
-}
+const deploy = require("./editor/deploy")
 
 export function deployCoreAsync(resp: pxtc.CompileResult) {
-    return pxt.editor.deployCoreAsync(resp, process.env["PXT_SERIAL"] ? false : true)
+    return deploy.deployCoreAsync(resp, process.env["PXT_SERIAL"] ? false : true)
         .then(() => {
             fs.writeFileSync("built/full-" + pxtc.BINARY_UF2, resp.outfiles[pxtc.BINARY_UF2], {
                 encoding: "base64"

cmds/pxtrequire.ts

@@ -1,4 +1,3 @@
-/// <reference path="../node_modules/pxt-core/typings/globals/node/index.d.ts"/>
 /// <reference path="../node_modules/pxt-core/built/pxtlib.d.ts" />
 
 import * as path from "path";

cmds/tsconfig.json

@@ -8,6 +8,7 @@
         "module": "commonjs",
         "rootDir": ".",
         "newLine": "LF",
-        "sourceMap": false
+        "sourceMap": false,
+        "types": ["node"]
     }
 }

docfiles/footer.html

@@ -0,0 +1,16 @@
+<footer class="ui inverted accent vertical footer segment hideprint" aria-hidden="false">
+    <div class="ui center aligned container">
+        <div class="ui container horizontal inverted small divided link list">
+            <!-- <a class="item" href="https://makecode.com/contact" target="_blank" rel="noopener">Contact Us</a> -->
+            <a class="item" href="https://makecode.com/privacy" target="_blank" rel="noopener">Privacy &amp; Cookies</a>
+            <a class="item" href="https://makecode.com/termsofuse" target="_blank" rel="noopener"> Terms Of Use</a>
+            <a class="item" href="https://makecode.com/trademarks" target="_blank" rel="noopener">Trademarks</a>
+            <div class="item">© 2018 Microsoft</div>
+            <!-- we need to force the browser to load this font -->
+            <div style='font-family: Icons; color: #010101;' aria-hidden="true">.</div>
+        </div>
+        <div class="ui container horizontal inverted small divided link list">
+            <a class="ui centered item" href="https://makecode.com/" title="Microsoft MakeCode" target="_blank" rel="noopener">Powered by Microsoft MakeCode</a>
+        </div>
+    </div>
+</footer>

docs/SUMMARY.md

@@ -1,5 +1,125 @@
 # @extends
 
+## Support #support
+
+* [Troubleshoot](/troubleshoot)
+* [LEGO Support](http://service.lego.com/)
+* [EV3 Manager](https://ev3manager.education.lego.com/)
+
+## Projects #projects
+
+* [Getting Started](/getting-started)
+    * [Try](/getting-started/try)
+    * [Use](/getting-started/use)
+
+* [Tutorials](/tutorials)
+    * [Wake Up!](/tutorials/wake-up)
+    * [Make An Animation](/tutorials/make-an-animation)
+    * [What Animal Am I?](/tutorials/what-animal-am-i)
+    * [Music Brick](/tutorials/music-brick)
+    * [Run Motors](/tutorials/run-motors)
+    * [Touch to Run](/tutorials/touch-to-run)
+    * [Touch Sensor Values](/tutorials/touch-sensor-values)
+    * [What Color?](/tutorials/what-color)
+    * [Line Following](/tutorials/line-following)
+    * [Red Light, Green Light](/tutorials/redlight-greenlight)
+    * [Object Near?](/tutorials/object-near)
+    * [Security Alert](/tutorials/security-alert)
+
+* [Coding](/coding)
+    * [Autonomous Parking](/coding/autonomous-parking)
+    * [Object Detection](/coding/object-detection)
+    * [Line Detection](/coding/line-detection)
+        
+* [Design Engineering](/design-engineering)
+    * [Make It Move Without Wheels](/design-engineering/make-it-move)
+    * [Make It Smarter and Faster](/design-engineering/make-it-smarter)
+    * [Make a System that Communicates](/design-engineering/make-it-communicate)
+
+* [Maker](/maker)
+    * [Make a Sound Machine](/maker/sound-machine)
+    * [Make a Security Gadget](/maker/security-gadget)
+
 ## Reference #reference
 
 * [Reference](/reference)
+    * [Brick](/reference/brick)
+        * [show string](/reference/brick/show-string)
+        * [show number](/reference/brick/show-number)
+        * [show value](/reference/brick/show-value)
+        * [show mood](/reference/brick/show-mood)
+        * [show image](/reference/brick/show-image)
+        * [clear screen](/reference/brick/clear-screen)
+        * [show ports](/reference/brick/show-ports)
+        * [on event](/reference/brick/button/on-event)
+        * [is pressed](/reference/brick/button/is-pressed)
+        * [was pressed](/reference/brick/button/was-pressed)
+        * [pause until](/reference/brick/button/pause-until)
+        * [set light](/reference/brick/set-status-light)
+        * [battery level](/reference/brick/battery-level)
+    * [Motors](/reference/motors)
+        * [run](/reference/motors/motor/run)
+        * [stop](/reference/motors/motor/stop)
+        * [reset](/reference/motors/motor/reset)
+        * [set brake](/reference/motors/motor/set-brake)
+        * [set inverted](/reference/motors/motor/set-inverted)
+        * [set regulated](/reference/motors/motor/set-regulated)
+        * [tank](/reference/motors/synced/tank)
+        * [steer](/reference/motors/synced/steer)
+        * [angle](/reference/motors/motor/angle)
+        * [speed](/reference/motors/motor/speed)
+        * [clear counts](/reference/motors/motor/clear-counts)
+        * [stop all motors](/reference/motors/stop-all)
+    * [Sensors](/reference/sensors)
+        * [Touch](/reference/sensors/touch-sensor)
+            * [on event](/reference/sensors/touch-sensor/on-event)
+            * [pause until](/reference/sensors/touch-sensor/pause-until)
+            * [is pressed](/reference/sensors/touch-sensor/is-pressed)
+            * [was pressed](/reference/sensors/touch-sensor/was-pressed)
+        * [Gyro](/reference/sensors/gyro)
+            * [angle](/reference/sensors/gyro/angle)
+            * [rate](/reference/sensors/gyro/rate)
+            * [reset](/reference/sensors/gyro/reset)
+        * [Ultrasonic](/reference/sensors/ultrasonic)
+            * [on event](/reference/sensors/ultrasonic/on-event)
+            * [distance](reference/sensors/ultrasonic/distance)
+            * [pause until](reference/sensors/ultrasonic/pause-until)
+        * [Infrared](/reference/sensors/infrared)
+            * [on event](/reference/sensors/infrared/on-event)
+            * [distance](reference/sensors/infrared/proximity)
+            * [pause until](reference/sensors/infrared/pause-until)
+        * [Infrared beacon](/reference/sensors/beacon)
+            * [on event](/reference/sensors/beacon/on-event)
+            * [pause until](/reference/sensors/beacon/pause-until)
+            * [is pressed](/reference/sensors/beacon/is-pressed)
+            * [was pressed](/reference/sensors/beacon/was-pressed)
+            * [set remote channel](/reference/sensors/beacon/set-remote-channel)
+        * [Color](/reference/sensors/color-sensor)
+            * [on color detected](/reference/sensors/color-sensor/on-color-detected)
+            * [pause until color detected](/reference/sensors/color-sensor/pause-until-color-detected)
+            * [on light detected](/reference/sensors/color-sensor/on-light-detected)
+            * [pause until light condition detected](/reference/sensors/color-sensor/pause-until-light-detected)
+            * [color](/reference/sensors/color-sensor/color)
+            * [light](/reference/sensors/color-sensor/ambient-light)
+    * [Music](/reference/music)
+        * [play sound effect](/reference/music/play-sound-effect)
+        * [play sound effect until done](/reference/music/play-sound-effect-until-done)
+        * [play tone](/reference/music/play-tone)
+        * [ring tone](/reference/music/ring-tone)
+        * [stop all sounds](/reference/music/stop-all-sounds)
+        * [rest](/reference/music/rest)
+        * [change tempo by](/reference/music/change-tempo-by)
+        * [set tempo](/reference/music/set-tempo)
+        * [note frequency](/reference/music/note-frequency)
+        * [beat](/reference/music/beat)
+        * [set volume](/reference/music/set-volume)
+    * [Control](/reference/control)
+        * [Timer](/reference/control/timer)
+            * [seconds](/reference/control/timer/seconds)
+            * [millis](/reference/control/timer/millis)
+            * [reset](/reference/control/timer/reset)
+            * [pause until](/reference/control/timer/pause-until)
+    * [Console](/reference/console)
+        * [log](/reference/console/log)
+        * [log value](/reference/console/log-value)
+        * [send to screen](/reference/console/send-to-screen)

docs/about.md

@@ -6,26 +6,32 @@ Welcome to the **Microsoft MakeCode** editor for the **@boardname@**!
 
 You can program the @boardname@ using [Blocks](/blocks) or [JavaScript](/javascript) in your web browser:
 
-```block
-input.buttonA.onEvent(ButtonEvent.Click, () => {
-    light.showRing(`blue blue blue blue blue blue blue blue blue blue`)
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, () => {
+    motors.largeA.run(50)
 })
 ```
 ```typescript
-input.buttonA.onEvent(ButtonEvent.Click, () => {
-    light.showRing(`blue blue blue blue blue blue blue blue blue blue`)
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, () => {
+    motors.largeA.run(50)
 })
 ```
 
 The editor work in [most modern browsers](/browsers), work [offline](/offline) once loaded and do not require any installation. 
 
-## [Compile and Flash: Your Program!](/device/usb)
+## Compile and Flash: Your Program!
 
 When you have your code ready, you connect your @boardname@ to a computer via a USB cable 
-**then press the reset button** so it appears as a mounted drive (named **CPLAYBOOT**). 
+so it appears as a mounted drive (named **EV3**). 
 
 Compilation to machine code from [Blocks](/blocks) or [JavaScript](/javascript) happens in the browser. You save the binary 
-program to a **.uf2** file, which you then copy to the **CPLAYBOOT** drive, which flashes the device with the new program.
+program to a **.uf2** file, which you then copy to the **EV3** drive, which flashes the device with the new program.
+
+### ~ hint
+
+Not seeing the **EV3** drive? Make sure to upgrade your firmware at https://ev3manager.education.lego.com/.
+
+### ~
 
 ## Simulator: Test Your Code
 
@@ -33,11 +39,7 @@ You can run your code using the micro:bit simulator, all within the confines of
 The simulator has support for the LED screen, buttons, as well as compass, accelerometer, and digital I/O pins.
 
 ```sim
-loops.forever(() => {
-    light.pixels.showAnimation(light.animation(LightAnimation.Rainbow), 1000)
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, () => {
+    motors.largeA.run(50)
 })
 ```
-
-```package
-light
-```

docs/blocks/loops.md

@@ -3,6 +3,6 @@
 ### #specific
 
 ```cards
-loops.forever(() => {});
-loops.pause(0)
+forever(() => {});
+pause(0)
 ```

docs/coding.md

@@ -0,0 +1,27 @@
+# Coding Activites
+
+
+## Projects
+
+```codecard
+[
+{
+  "name": "Autonomous Parking",
+  "description": "Design cars that can park themselves safely without driver intervention.",
+  "url":"/coding/autonomous-parking",
+  "imageUrl": "/static/lessons/autonomous-parking.png",
+  "cardType": "side"
+}, {
+  "name": "Object Detection",
+  "description": "Design ways to avoid accidents between vehicles and objects in the road.",
+  "url":"/coding/object-detection",
+  "imageUrl": "/static/lessons/object-detection.jpg",
+  "cardType": "side"
+}, {
+  "name": "Line Detection",
+  "description": "Design ways to improve driving safety by helping to prevent drivers from falling asleep and causing an accident.",
+  "url":"/coding/line-detection",
+  "imageUrl": "/static/lessons/line-detection.jpg",
+  "cardType": "side"
+}]
+```

docs/coding/autonomous-parking.md

@@ -0,0 +1,171 @@
+# Autonomous Parking
+
+Design cars that can park themselves safely without driver intervention.
+
+![Autonomous parking graphic](/static/coding/autonomous-parking/auto-parking-connect.jpg)
+
+## Connect
+
+**Think about:**
+
+* How do autonomous cars work?
+* What would it take to ensure that autonomous cars are safe?
+* What types of movements do autonomous cars need to perform?
+
+## Construct 
+
+### Build
+
+Build a @boardname@ vehicle that can park itself safely without driver intervention. Start by constructing this model:
+
+[![EV3- Robot Driving Base](/static/coding/autonomous-parking/ev3-robot-driving-base.jpg)](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/building-instructions/ev3-rem-driving-base-79bebfc16bd491186ea9c9069842155e.pdf)
+
+### Check
+
+Before you program, check:
+
+* Are all the wires correctly connected from the motors to ports B and C?
+* Are the wheels correctly installed?
+* Are the wheels rotating freely?
+
+### Program 
+
+Write a program that will make the robot turn three times in various ways.
+
+**Think about:**
+
+* How will you make the robot turn in different ways?
+* How can the robot make a three point turn?
+
+### ~hint
+
+Consider using these blocks in your solution:
+
+```block
+motors.largeBC.tank(50, 50)
+pause(500)
+```
+
+### ~
+
+### Sample Solution - Three Point Turn
+
+1. When the brick button is pressed, turn the driving base right and stop after 1.5 seconds.
+2. Turn the driving base left and stop after 1 second.
+3. Move the driving base forward for 3 seconds.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeBC.tank(75, 30)
+    loops.pause(1500)
+    motors.largeBC.tank(-30, -75)
+    loops.pause(1000)
+    motors.largeBC.tank(50, 50)
+    loops.pause(3000)
+})
+```
+
+### Download and test
+
+Click Download and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Contemplate
+
+Choose one of the following autonomous driving scenarios and create a program for it:
+
+* Parallel parking
+* Angle parking
+* Perpendicular parking
+
+### ~hint
+
+Document pseudocode for your program before choosing programming blocks.
+
+### ~
+
+### Sample Solution - Parallel Parking
+
+1. When the brick button is pressed, drive forward in a straight line for 3 rotations.
+2. Wait for 1 second.
+3. Reverse motor rotation while turning for 1.5 rotations.
+4. Reverse motor rotation while turning the other way for 1.5 rotations.
+5. Drive backward in a straight line for 0.5 rotations.
+6. Drive forward in a straight line for 0.5 rotations.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeBC.steer(0, 50, 3, MoveUnit.Rotations)
+    pause(1000)
+motors.largeBC.steer(-50, -50, 1.5, MoveUnit.Rotations)
+    motors.largeBC.steer(50, -50, 1.5, MoveUnit.Rotations)
+    motors.largeBC.steer(0, -50, 0.5, MoveUnit.Rotations)
+    motors.largeBC.steer(0, 50, 0.5, MoveUnit.Rotations)
+})
+```
+
+### Download and test
+
+Click Download and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+### Differentiation
+
+Create a program that simulates displaying appropriate warning lights while parking. 
+
+### ~hint
+
+Consider using this block in your solution:
+
+```block
+brick.setStatusLight(StatusLight.OrangeFlash)
+```
+
+### ~
+
+### Sample Solution - Simulating Reverse Gear and Reverse Warning Lights
+
+1. When the brick button is pressed, drive forward in a straight line for 3 rotations.
+2. Wait for 1 second.
+3. Set brick status light to orange flash.
+4. Reverse motor rotation while turning for 1.5 rotations.
+5. Reverse motor rotation while turning the other way for 1.5 rotations.
+6. Drive backward in a straight line for 0.5 rotations.
+7. Set brick status light to off.
+8. Drive forward in a straight line for 0.5 rotations.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeBC.steer(0, 50, 3, MoveUnit.Rotations)
+    pause(1000)
+    brick.setStatusLight(StatusLight.OrangeFlash)
+    motors.largeBC.steer(-50, -50, 1.5, MoveUnit.Rotations)
+    motors.largeBC.steer(50, -50, 1.5, MoveUnit.Rotations)
+    motors.largeBC.steer(0, -50, 0.5, MoveUnit.Rotations)
+    brick.setStatusLight(StatusLight.Off)
+    motors.largeBC.steer(0, 50, 0.5, MoveUnit.Rotations)
+})
+```
+
+### Download and test
+
+Click Download and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+### Share
+
+**Think about:**
+
+* What challenged you?
+* Were there any surprises?
+* How can you improve your program?
+* Can your program be more streamlined? Have you used too many blocks?
+* Is there a more efficient way to build your program?
+* How can your program be used in real-world scenarios?
+
+## Continue
+
+* Click on the JavaScript tab and experiment with changing the values in the code.
+* Add a custom image or sounds from the Brick or Music menus.
+* Create a video of your project, especially your final presentation and your robot’s performance. Explain some important features of your software program. 
+* Include an image of your program with comments. 
+* Add a team photograph! 
+
+Congratulations! What will you design next?

docs/coding/cruise-control.md

@@ -0,0 +1,65 @@
+# Cruise Control
+
+Learn how to set and adjust motor speeds.
+
+## Activity 1
+
+Increase motor speed when touch sensor `1` is pressed.
+
+```blocks
+let speed = 0;
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
+    if (speed < 100)
+        speed = speed + 10;
+    motors.largeBC.run(speed);
+}) 
+```
+
+## Activity 2
+
+Add a "reduce" motor speed action when touch sensor `2` is pressed.
+
+```blocks
+let speed = 0;
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
+    if (speed < 100)
+        speed = speed + 10;
+    motors.largeBC.run(speed);
+}) 
+sensors.touch2.onEvent(ButtonEvent.Pressed, function () {
+    if (speed > -100)
+        speed = speed - 10;
+    motors.largeBC.run(speed);
+}) 
+```
+
+## Activity 3
+
+Refactor your code by moving the speed increase and speed decrease code into ``||functions:accelerate||`` and ``||functions:decelerate||`` functions. Run the motors at the new speed in an ``||functions:update||`` function.
+
+```blocks
+let speed = 0
+function decelerate() {
+    if (speed > -100) {
+        speed = speed - 10
+    }
+}
+function accelerate() {
+    if (speed < 100) {
+        speed = speed + 10
+    }
+}
+function update() {
+    brick.clearScreen()
+    brick.showString("speed: " + speed, 1)
+    motors.largeBC.run(speed)
+}
+sensors.touch2.onEvent(ButtonEvent.Pressed, function () {
+    accelerate()
+    update()
+})
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
+    decelerate()
+    update()
+})
+```

docs/coding/ignition.md

@@ -0,0 +1,48 @@
+# Ignition
+
+Explore sensor events and sensor status.
+
+## Activity 1
+
+Wait for a touch sensor press or ultrasonic object detection. Show an expression on the screen when they happen.
+
+```blocks
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
+    brick.showImage(images.eyesDizzy)
+})
+sensors.ultrasonic4.onEvent(UltrasonicSensorEvent.ObjectDetected, function () {
+    brick.showImage(images.eyesTiredMiddle)
+})
+brick.showImage(images.eyesSleeping)
+```
+
+## Activity 2
+
+Play some motor sounds if touch sensor `1` is pressed at the same moment when and object comes close.
+
+```blocks
+while (true) {
+    if (sensors.touch1.isPressed() &&
+        sensors.ultrasonic4.distance() < 10) {
+        music.playSoundEffectUntilDone(sounds.mechanicalMotorStart)
+        music.playSoundEffectUntilDone(sounds.mechanicalMotorIdle);
+    }
+    pause(1);
+}
+```
+
+## Activity 3
+
+Play some motor sounds if touch sensor `1` is pressed when both the `enter` button is pressed on the brick and an object comes close.
+
+```blocks
+while (true) {
+    if (sensors.ultrasonic4.distance() < 10 &&
+        sensors.touch1.isPressed() &&
+        brick.buttonEnter.isPressed()) {
+        music.playSoundEffectUntilDone(sounds.mechanicalMotorStart)
+        music.playSoundEffectUntilDone(sounds.mechanicalMotorIdle);
+    }
+    pause(1);
+}
+```

docs/coding/light-the-way-1.md

@@ -0,0 +1,9 @@
+# Light the way Activity 1
+
+```blocks
+sensors.color3.onLightDetected(LightIntensityMode.Ambient, Light.Dark, function () {
+    brick.showImage(images.objectsLightOn)
+    pause(5000)
+    brick.clearScreen()
+})
+```

docs/coding/light-the-way-2.md

@@ -0,0 +1,10 @@
+# Light the way Activity 2
+
+```blocks
+sensors.color3.onLightDetected(LightIntensityMode.Ambient, Light.Bright, function () {
+    brick.clearScreen()
+})
+sensors.color3.onLightDetected(LightIntensityMode.Ambient, Light.Dark, function () {
+    brick.showImage(images.objectsLightOn)
+})
+```

docs/coding/light-the-way-3.md

@@ -0,0 +1,13 @@
+# Light the way Activity 3
+
+```blocks
+sensors.color3.onLightDetected(LightIntensityMode.Ambient, Light.Bright, function () {
+    brick.clearScreen()
+})
+sensors.color3.onLightDetected(LightIntensityMode.Ambient, Light.Dark, function () {
+    brick.showImage(images.objectsLightOn)
+})
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
+    brick.showImage(images.objectsLightOn);
+})
+```

docs/coding/line-detection.md

@@ -0,0 +1,239 @@
+# Line Detection
+
+Design ways to improve driving safety by helping to prevent drivers from falling asleep and causing an accident.
+
+![Car following the line on the road](/static/coding/line-detection/car-road-line.jpg)
+
+## Connect
+
+Think about:
+
+* How can autonomous cars react to different traffic light signals?
+* What can happen if a driver falls asleep while driving?
+* How can we detect when a driver is falling asleep?
+
+## Construct
+
+### Build
+
+Build a @boardname@ vehicle that can help prevent drivers from falling asleep and causing an accident. Start by constructing this model:
+
+[![EV3 robot with color sensor](/static/coding/line-detection/ev3-robot-color-sensor-down.jpg)](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/building-instructions/ev3-rem-color-sensor-down-driving-base-d30ed30610c3d6647d56e17bc64cf6e2.pdf)
+
+Build red and green “lights” for your robot to detect. You can use LEGO bricks, colored tape, or marker on white paper. Building instructions:
+
+[![IMAGE: Color Squares](/static/coding/line-detection/ev3-color-squares.jpg)](https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/color%20squares-0a88dfd98bb2e64b5b8151fc422bae36.pdf)
+
+### Check
+
+Before you program, check:
+
+* Are all the wires correctly connected from the motors to ports B and C?
+* Are the wheels correctly installed?
+* Are the wheels rotating freely?
+* Are the wires connected from the Color Sensor to port 3?
+
+![EV3 Driving Base](/static/coding/line-detection/ev3-robot-driving-base.jpg)
+
+### Program
+
+Autonomous cars need to recognize and respond to traffic lights automatically. Create a program that will make your robot stop at red lights. Make sure your robot is only responding to the color red. Once you have succeeded, program your robot to drive forward again when the light changes from red to green.
+
+Before you program, think about:
+
+* How will you program the robot to detect a color?
+* How will you program the robot to stop at a color?
+* Which programming blocks will you use?
+
+### ~ hint
+
+Consider using these blocks in your solution:
+
+```block
+loops.forever(function () {
+	
+})
+motors.largeBC.steer(0, 50)
+sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+motors.stopAll()
+```
+
+### ~
+
+### Sample Solution - Red light detection
+
+1. Loop forever.
+2. Start motors ``B`` and ``C`` (drive forward).
+3. Wait for the color sensor to detect the color red.
+4. Stop all motors.
+
+```blocks
+loops.forever(function () {
+    motors.largeBC.steer(0, 50)
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+    motors.stopAll()
+})
+```
+
+### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. 
+
+Congratulations! Your robot can stop at a red light. 
+
+Now add to your program and have your robot to drive forward again when the light changes from red to green.
+
+### Sample Solution - Red and green light detection in a loop
+
+1. Start motors ``B`` and ``C`` (drive forward).
+2. Wait for the color sensor to detect the color red.
+3. Stop all motors.
+4. Wait for the color sensor to detect the color green.
+5. Loop forever.
+
+```blocks
+loops.forever(function () {
+    motors.largeBC.steer(0, 50)
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+    motors.stopAll()
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Green)
+})
+```
+
+### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. 
+
+## Contemplate
+
+To simulate what could happen if a driver falls asleep while driving, your robot could sound an alarm signal when it crosses the line. This feature is often available in new cars.
+
+Program your robot to perform this function.
+
+Draw a dark line with tape or marker for your robot to cross.
+
+### ~hint
+
+Consider using these blocks in your solution:
+
+```block 
+motors.largeBC.steer(0, 50)
+music.playSoundEffect(sounds.systemGeneralAlert)
+```
+### ~
+
+### Sample Solution - Line detection in a loop
+
+1. Start motors ``B`` and ``C`` (drive forward with a curve toward the line).
+2. Wait for the color sensor to detect the color black.
+3. Play sound effect ``system general alert``.
+4. Start motors ``B`` and ``C`` (drive forward with a curve away from the line).
+5. Wait for the color sensor to detect the color white.
+6. Loop forever.
+
+```blocks
+loops.forever(function () {
+    motors.largeBC.steer(-30, 20)
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Black)
+    music.playSoundEffect(sounds.systemGeneralAlert)
+    motors.largeBC.steer(30, 20)
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.White)
+})
+```
+
+#### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. 
+
+#### Differentiation
+
+Program your robot to drive on “autopilot” along a given route. You will need to create a program that recognizes and responds to a dark line (or white line). You will create a line-following program and your robot will need to travel along the line without losing contact with it.
+
+You will need to constantly debug your program in order to make your robot travel as smoothly as possible along the line.
+
+### ~hint
+
+Consider using these blocks in your solution:
+
+```block
+while (true) {
+	
+}
+motors.largeBC.steer(0, 50)
+```
+
+> **- OR -**
+
+```block
+if (true) {
+	
+} else {
+
+}
+```
+
+### ~
+
+### Sample Solutions - Line Following in Loop
+
+#### Method 1
+
+1. While the Color Sensor detects the color black, start motors ``B`` and ``C`` (drive forward with a curve toward the line).
+2. While the Color Sensor detects the color white, start motors ``B`` and ``C`` (drive forward with a curve away from the line).
+3. Loop forever.
+
+```blocks
+forever(function () {
+    while (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Black)
+        motors.largeBC.steer(-30, 50)
+    }
+    while (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.White)
+        motors.largeBC.steer(30, 50)
+    }
+})
+```
+
+#### Method 2
+
+1. If the Color Sensor detects the color black, start motors ``B`` and ``C`` (drive forward with a curve toward the line).
+Else the Color Sensor detects the color white, start motors ``B`` and ``C`` (drive forward with a curve away from the line).
+2. Loop forever.
+
+```blocks
+forever(function () {
+    if (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Black)
+        motors.largeBC.steer(-30, 50)
+    } else {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.White)
+        motors.largeBC.steer(30, 50)
+    }
+})
+```
+
+### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. 
+
+### Share
+
+Think about:
+
+* What challenged you?
+* Were there any surprises?
+* How can you improve your program?
+* Can your program be more streamlined? Have you used too many blocks?
+* Is there a more efficient way to build your program?
+* How can your program be used in real-world scenarios?
+
+Personalize:
+
+* Click on the **JavaScript** tab and experiment with changing the values in the code.
+* Add a custom image or sounds from the ``||brick:Brick||`` or ``||music:Music||`` menus.
+* Create a video of your project, especially your final presentation and your robot’s performance. Explain some important features of your software program. 
+* Include an image of your program with comments. 
+* Add a team photograph! 
+
+Congratulations! What will you design next?

docs/coding/object-detection.md

@@ -0,0 +1,137 @@
+# Object Detection
+
+Design ways to avoid accidents between vehicles and objects in the road.
+
+![Deer in the road](/static/coding/object-detection/road-deer.jpg)
+
+## Connect 
+
+Think about:
+
+* In what driving situations can a car hit an obstacle?
+* What do you need to be aware of to avoid collisions with obstacles?
+* What causes traffic jams in high density areas?
+
+## Construct 
+
+### Build
+
+Build a @boardname@ vehicle that can avoid accidents between vehicles and objects in the road. Start by constructing this model:
+
+[![EV3 Robot Driving Base](/static/coding/object-detection/ev3-robot-driving-base.jpg)](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/building-instructions/ev3-ultrasonic-sensor-driving-base-61ffdfa461aee2470b8ddbeab16e2070.pdf)
+
+Build an obstacle for your robot to detect. You can build the **cuboid model** out of LEGO bricks or an obstacle of your choice. 
+
+[![Cubiod block](/static/coding/object-detection/ev3-cuboid.jpg)](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/building-instructions/ev3-cuboid-dc93b2e60bed2981e76b3bac9ea04558.pdf)
+
+### Check
+
+Before you program, check:
+
+* Are all the wires correctly connected from the motors to ports B and C?
+* Are the wheels correctly installed?
+* Are the wheels rotating freely?
+* Are the wires connected from the Ultrasonic Sensor to port 4?
+
+### Program
+
+* Program your robot to detect any obstacles that might appear while the robot is moving forward (or backward).
+* Make the robot stop when it detects an object that is less than 20 cm away.
+
+Before you program, think about:  
+* How will you program the robot to detect obstacles?
+* How will you program the robot to stop at obstacles?
+* Which programming blocks will you use?
+
+### ~hint
+
+Consider using these blocks in your solution:
+
+```block
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+
+})
+motors.largeBC.steer(0, 50)
+pauseUntil(() => true)
+let near = sensors.ultrasonic4.distance() < 20
+motors.stopAll()
+```
+
+### ~
+
+### Sample Solution 
+
+1. Start the program when EV3 ``enter`` button is pressed.
+2. Turn motors ``B`` and ``C`` on at speed ``50``.
+3. Wait until Ultrasonic Sensor detects an obstacle at a distance of less than ``20`` cm.
+4. Stops all motors.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeBC.steer(0, 50)
+    pauseUntil(() => sensors.ultrasonic4.distance() < 20)
+    motors.stopAll()
+})
+```
+
+### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the ``center`` button on the EV3 Brick to run the program.
+
+## Contemplate
+
+On the road, when a driver sees and object, they slow their car down before coming to a full stop. 
+
+Program your EV3 Driving Base to do the same.
+
+If the Ultrasonic Sensor:
+
+* Detects an object less than `10` cm away, make the robot stop.
+* Detects an object between `10` and `20` cm away, make the robot slow down.
+* Does not detect any object, continue to move at full speed.
+
+### ~hint
+
+Consider using this block in your solution:
+ 
+```block
+if (true) {
+}
+```
+
+### ~
+
+### Sample Solution 
+
+```blocks
+loops.forever(function () {
+    motors.largeBC.steer(0, 50)
+    if (sensors.ultrasonic4.distance() < 10) {
+        motors.stopAll()
+    } else if (sensors.ultrasonic4.distance() < 20) {
+        motors.largeBC.steer(0, 10)
+    }
+})
+```
+
+### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the ``center`` button on the EV3 Brick to run the program.
+
+## Continue 
+
+* Get together with other building teams and make a traffic jam by placing all of your robots in a line with varying amounts of space between them.
+* Have everyone start their robots at the same time and see what happens.
+* Refine your programs so that all of the robots continue driving at the same speed with equal distances between them.
+* Click on the JavaScript tab and experiment with changing the values in the code.
+* Add a custom image or sounds from the Brick or Music menus.
+
+### Share
+
+* Share what you think “efficiency in programming” means.
+* Explore the different solutions other programmers came up with.
+* Create a video of your project, especially your final presentation and your robot’s performance. Explain some important features of your software program. 
+* Include an image of your program with comments. 
+* Add a team photograph! 
+
+Congratulations! What will you design next?

docs/coding/reverse-beeper-1.md

@@ -0,0 +1,11 @@
+# Reverse Beeper Activity 1
+
+```blocks
+forever(function () {
+    music.playTone(440, sensors.ultrasonic4.distance());
+    pause(50)
+})
+motors.largeBC.run(-20);
+sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectNear);
+motors.largeBC.stop();
+```

docs/coding/reverse-beeper-2.md

@@ -0,0 +1,13 @@
+# Reverse Beeper Activity 2
+
+```blocks
+forever(function () {
+    if (motors.largeB.speed() != 0 && sensors.ultrasonic4.distance() < 20) {
+        music.playTone(440, sensors.ultrasonic4.distance());
+        pause(50)
+    }
+})
+motors.largeBC.run(-20);
+sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectNear);
+motors.largeBC.stop();
+```

docs/coding/reverse-beeper-3.md

@@ -0,0 +1,20 @@
+# Reverse Beeper Activity 2
+
+```blocks
+let beep = false
+beep = true
+control.runInParallel(function () {
+    motors.largeBC.run(-20)
+    sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectNear)
+    motors.largeBC.stop()
+    beep = false
+})
+control.runInParallel(function () {
+    while (beep) {
+        if (sensors.ultrasonic4.distance() < 20) {
+            music.playTone(440, sensors.ultrasonic4.distance())
+            pause(50)
+        }
+    }
+})
+```

docs/coding/reversing-the-robot-1.md

@@ -0,0 +1,14 @@
+# Reversing the robot Activity 1
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    motors.largeBC.run(50)
+    sensors.touch1.pauseUntil(ButtonEvent.Pressed)
+    motors.largeBC.run(0)
+    pause(1000)
+    brick.setStatusLight(StatusLight.OrangeFlash)
+    motors.largeBC.run(-50)
+    pause(2000)
+    motors.largeBC.run(0)
+})
+```

docs/coding/reversing-the-robot-2.md

@@ -0,0 +1,15 @@
+# Reversing the robot Activity 2
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    sensors.touch1.pauseUntil(ButtonEvent.Pressed)
+    motors.largeBC.run(50)
+    sensors.touch2.pauseUntil(ButtonEvent.Pressed)
+    motors.largeBC.run(0)
+    pause(1000)
+    brick.setStatusLight(StatusLight.OrangeFlash)
+    motors.largeBC.run(-50)
+    pause(2000)
+    motors.largeBC.run(0)
+})
+```

docs/coding/reversing-the-robot-3.md

@@ -0,0 +1,19 @@
+# Reversing the robot Activity 3
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    brick.showImage(images.eyesSleeping)
+    sensors.touch1.pauseUntil(ButtonEvent.Pressed)
+    brick.showImage(images.eyesNeutral)
+    motors.largeBC.run(50)
+    sensors.touch2.pauseUntil(ButtonEvent.Pressed)
+    brick.showImage(images.eyesTiredMiddle)
+    motors.largeBC.run(0)
+    pause(1000)
+    brick.setStatusLight(StatusLight.OrangeFlash)
+    brick.showImage(images.eyesDizzy)
+    motors.largeBC.run(-50)
+    pause(2000)
+    motors.largeBC.run(0)
+})
+```

docs/coding/roaming-1.md

@@ -0,0 +1,32 @@
+# Roaming Activity 1
+
+```blocks
+let drive: number[] = []
+brick.buttonLeft.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(1)
+})
+brick.buttonRight.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(3)
+})
+brick.buttonUp.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(4)
+})
+brick.buttonDown.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(5)
+})
+pauseUntil(() => drive.length >= 5)
+pause(1000)
+music.playSoundEffectUntilDone(sounds.communicationGo)
+for (let d of drive) {
+    if (d == 1) {
+        motors.largeC.run(50, 360, MoveUnit.Degrees)
+    } else if (d == 3) {
+        motors.largeB.run(50, 360, MoveUnit.Degrees)
+    } else if (d == 4) {
+        motors.largeBC.run(50, 360, MoveUnit.Degrees)
+    } else {
+        motors.largeBC.run(-50, 360, MoveUnit.Degrees)
+    }
+}
+music.playSoundEffectUntilDone(sounds.communicationGameOver)
+```

docs/coding/roaming-2.md

@@ -0,0 +1,36 @@
+# Roaming Activity 2
+
+```blocks
+let drive: number[] = []
+brick.buttonLeft.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(1)
+    music.playSoundEffectUntilDone(sounds.systemClick)
+})
+brick.buttonRight.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(3)
+    music.playSoundEffectUntilDone(sounds.systemClick)
+})
+brick.buttonUp.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(4)
+    music.playSoundEffectUntilDone(sounds.systemClick)
+})
+brick.buttonDown.onEvent(ButtonEvent.Bumped, function () {
+    drive.push(5)
+    music.playSoundEffectUntilDone(sounds.systemClick)
+})
+brick.buttonEnter.pauseUntil(ButtonEvent.Bumped);
+pause(1000)
+music.playSoundEffectUntilDone(sounds.communicationGo)
+for (let d of drive) {
+    if (d == 1) {
+        motors.largeC.run(50, 360, MoveUnit.Degrees)
+    } else if (d == 3) {
+        motors.largeB.run(50, 360, MoveUnit.Degrees)
+    } else if (d == 4) {
+        motors.largeBC.run(50, 360, MoveUnit.Degrees)
+    } else {
+        motors.largeBC.run(-50, 360, MoveUnit.Degrees)
+    }
+}
+music.playSoundEffectUntilDone(sounds.communicationGameOver)
+```

docs/coding/three-point-turn-1.md

@@ -0,0 +1,12 @@
+# Three Point Turn Activity 1
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    motors.largeBC.tank(75, 30)
+    pause(1500)
+    motors.largeBC.tank(-30, -75)
+    pause(1000)
+    motors.largeBC.tank(50, 50)
+    pause(3000)
+})
+```

docs/coding/three-point-turn-2.md

@@ -0,0 +1,14 @@
+# Three Point Turn Activity 2
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    motors.largeBC.tank(75, 30)
+    pause(1500)
+    motors.largeBC.tank(-30, -75)
+    sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectNear);
+    motors.largeBC.tank(0, 0)
+    pause(1000)
+    motors.largeBC.tank(50, 50)
+    pause(3000)
+})
+```

docs/coding/three-point-turn-3.md

@@ -0,0 +1,15 @@
+# Three Point Turn Activity 3
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    motors.largeBC.tank(75, 30)
+    pause(1500)
+    motors.largeBC.tank(-30, -75)
+    sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectNear);
+    motors.largeBC.tank(0, 0)
+    music.playSoundEffect(sounds.animalsDogBark1)
+    pause(1000)
+    motors.largeBC.tank(50, 50)
+    pause(3000)
+})
+```

docs/coding/traffic-lights-1.md

@@ -0,0 +1,9 @@
+# Traffic Lights Activity 1
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    motors.largeBC.tank(20, 20)
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+    motors.largeBC.tank(0, 0)
+})
+```

docs/coding/traffic-lights-2.md

@@ -0,0 +1,10 @@
+# Traffic Lights Activity 2
+
+```blocks
+sensors.color3.onColorDetected(ColorSensorColor.Red, function () {
+    motors.largeBC.tank(0, 0)  
+})
+sensors.color3.onColorDetected(ColorSensorColor.Green, function () {
+    motors.largeBC.tank(20, 20)
+})
+```

docs/coding/traffic-lights-3.md

@@ -0,0 +1,11 @@
+# Traffic Lights Activity 3
+
+```blocks
+forever(function () {
+    if (sensors.color3.light(LightIntensityMode.Reflected) < 15) {
+        motors.largeBC.tank(30, 12)
+    } else {
+        motors.largeBC.tank(12, 30)
+    }
+})
+```

docs/design-engineering.md

@@ -0,0 +1,29 @@
+# Design Engineering Projects
+
+## Projects
+
+```codecard
+[
+    {
+        "name": "Make It Move Without Wheels",
+        "description": "Design, build and program a robot that can move itself using no wheels for locomotion.",
+        "imageUrl": "/static/lessons/make-it-move-without-wheels.png",
+        "url": "/design-engineering/make-it-move",
+        "cardType": "side"
+    },
+    {
+        "name": "Make It Smarter and Faster",
+        "description": "Design, build and program a robotic creature that can sense its environment and respond by moving.",
+        "imageUrl": "/static/lessons/make-it-smarter-and-faster.png",
+        "url": "/design-engineering/make-it-smarter",
+        "cardType": "side"
+    },
+    {
+        "name": "Make a System that Communicates",
+        "description": "Design, build and program a robotic system that follows a path and communicates its position at least twice along the way.",
+        "imageUrl": "/static/lessons/make-a-system-that-communicates.png",
+        "url": "/design-engineering/make-it-communicate",
+        "cardType": "side"
+    }
+]
+```

docs/design-engineering/make-it-communicate.md

@@ -0,0 +1,151 @@
+# Make A System That Communicates
+
+## Connect 
+
+### Design Brief
+
+Design, build and program a robotic system that follows a path and communicates its position at least twice along the way.
+
+https://www.youtube.com/watch?v=6piMI1JPDQc
+
+* Robotic systems are built from smaller, related subsystems. Look at the automobile system shown in the video. What subsystems can you see?
+* What kinds of robots follow a path?
+* What kind of system do you want to make?
+
+### Brainstorm
+
+Discuss different solutions to the design brief.
+
+Think about:
+* What kind of motorized mechanism can be used to control the movements of a robot?
+* How can the robot sense where it is along the path?
+* How can the robot communicate its position?
+ 
+![EV3 + LEGO Bricks](/static/lessons/make-it-communicate/ev3-plus-parts.jpg)
+
+## Construct 
+
+### Build
+
+You can start by tinkering with the LEGO elements in the picture and then build on.
+
+More building ideas:
+
+[![EV3 Frames](/static/lessons/make-it-communicate/ev3-frames.jpg)](https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/ev3%20frames-5054ee378e624fb4cb31158d2fc8e5cf.pdf)
+
+[![Tracks](/static/lessons/make-it-communicate/ev3-tracks.jpg)](https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/tracks-32d7554813af3f25cf5012d54a4bad2b.pdf)
+
+[![Color Sensor 2](/static/lessons/make-it-communicate/ev3-color-sensor2.jpg)](https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/color%20sensor_v2-e7fd54b6fa3cdfe36f414c1d2510f9cb.pdf)
+
+
+Build a path for your robot to follow. You can use electrical tape on a floor, or marker on paper. You can use objects as milestones to indicate a path that can be detected by either the Touch Sensor, Color Sensor, or Ultrasonic Sensor. 
+
+### Program 
+
+Before you program, think about: 
+ 
+* How will you program the robot to follow a path?
+* How will you program the robot to communicate its position?
+* Which programming blocks will you use?
+
+### ~hint
+
+Explore the different Motor and Sensor blocks in the programming menu.
+
+### ~
+
+### Sample Solution 
+
+[![Video: EV3 Track Rover](/static/lessons/make-it-communicate/ev3-track-rover.jpg)](https://legoeducation.23video.com/v.ihtml/player.html?token=79c99735f906403a4dd7f2909935983d&source=embed&photo%5fid=19857954)
+
+The Track Rover follows a path using the color sensor. It identifies two locations by color.
+
+Track Rover solution combines these building ideas:
+
+* EV3 frames
+* Tracks
+* Color sensor 2
+
+Two copies of the tracks are built: one for the right side and a mirror image for the left side.
+
+[![Track rover assembled](/static/lessons/make-it-communicate/ev3-track-rover2.jpg)](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/ev3-dep/building%20instructions/track-rover-bi-6aadb1b053df0c58a0dea108b5ce0eea.pdf)
+
+### Sample Program Solution 
+
+This program works with the Track Rover. If you create a different robot, adjust the program to fit your solution. 
+
+Program summary: 
+
+* If the Color Sensor sees black, Motor B runs at -50 power and Motor C turns off.
+* If the Color Sensor sees white, Motor B turns off and Motor C runs at -50 power.
+* If the Color Sensor sees green, all motors stop and the green sound plays. 
+* The robot waits one second, then motors move forward.
+* If the Color Sensor sees red, all motors stop, and the red sound plays.
+* The robot waits one second, then motors move forward.
+* Loops unlimited.
+
+```blocks
+forever(function () {
+    if (sensors.color3.color() == ColorSensorColor.Black) {
+        motors.largeB.run(-50)
+        motors.largeC.run(0)
+    } else if (sensors.color3.color() == ColorSensorColor.White) {
+        motors.largeC.run(-50)
+        motors.largeB.run(0)
+    } else if (sensors.color3.color() == ColorSensorColor.Green) {
+        motors.stopAll()
+        music.playSoundEffectUntilDone(sounds.colorsGreen)
+        motors.largeBC.run(-50)
+    } else if (sensors.color3.color() == ColorSensorColor.Red) {
+        motors.stopAll()
+        music.playSoundEffectUntilDone(sounds.colorsRed)
+        motors.largeBC.run(-50)
+    }
+})
+```
+
+### Download and test
+
+Click Download and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Contemplate 
+
+### Test and Analyze 
+
+As you work on your solution:
+
+1. Describe one part of your design that worked especially well. 
+2. Describe one design change that you had to make. 
+3. What will you try next? 
+
+
+### Review and Revise 
+
+Take a moment to reflect on your robot solution. 
+
+Think about:
+
+* Can the robot’s movement be more accurate? 
+* What are some ways that others have solved the problem?
+
+Describe two ways you could improve your robot.
+
+## Continue 
+
+### Personalize your project
+
+* Add/remove LEGO elements to improve the way your robot moves. 
+* Click on the JavaScript tab and experiment with changing the values in the code.
+* Add a custom image or sounds by adding blocks from the Brick or Music menus.
+
+## Communicate 
+
+Here are some ideas:
+
+* Create a video of your project, especially your final presentation and your robot’s performance. 
+* Explain some important features of your software program. 
+* Produce a building guide for your model by taking a series of photographs as you deconstruct it. 
+* Include an image of your program with comments. 
+* Add a team photograph! 
+
+Congratulations! What will you design next?

docs/design-engineering/make-it-move.md

@@ -0,0 +1,97 @@
+# Make It Move Without Wheels
+
+## Connect
+
+### Design Brief
+
+Design, build and program a robot that can move itself using no wheels for locomotion.
+
+![Make it move banner](/static/lessons/make-it-move/make-it-move-without-wheels.png)
+
+Your robot will:
+
+* Go a distance of at least 30cm
+* Use at least one motor
+* Use NO wheels for locomotion
+
+### Brainstorm
+
+In nature, creatures use many methods to get around. None of them, however, use wheels to move. Can we copy the method of animal locomotion with our robot? Using motors and legs, make a robot that can move without using any wheels.
+
+## Construct
+
+### Build
+
+Think about a creature’s movement for inspiration. Will you make the robot walk, crawl, hop, or wiggle?  Your mechanism can be attached or unattached to the EV3 brick. You can start by tinkering with the LEGO elements in the picture above and then build on.
+
+### Building Hint
+
+If you want some building help you can follow these instructions.
+
+[![Toddle Bot](/static/lessons/make-it-move/toddle-bot.jpg)](https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/toddle%20bot-3dcad146d7f5deac4753f93e9dcc0739.pdf)
+
+### Program
+
+Before you program, think about:
+
+* How will you program the robot to move? 
+* How will you program the robot to stop?
+* How will you program the robot to display the distance moved?
+
+Which programming blocks will you use:
+
+* To turn on and turn off the motor or motors? 
+* To display the distance moved? 
+
+### Sample Code
+
+Example code of a robot that moves without wheels using one motor:
+
+* The robot moves with ``large motor D`` rotating at ``-100`` speed
+* The robot moves for ``30000`` milliseconds (30 seconds)
+* The robot stops 
+* The robot displays the text ``"30cm"``
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeD.run(-100)
+    loops.pause(30000)
+    motors.stopAll()
+    brick.showString("30cm", 1)
+})
+```
+
+### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Contemplate 
+
+### Test and Analyze
+
+Think about:
+
+* Is the robot using something other than wheels to move? Trace the movement from the motor axle to the mechanism(s) that drives the robot forward, backward or sideways. Wheels can be used to stabilize the robot but not to drive it.
+* Does the robot display the distance moved? Is it accurate? How do you know?
+* What is one part of your design that worked well?
+* What is a change that you need to make?
+* What will you try next?
+
+## Continue
+
+### Personalize your project
+
+* Add/remove LEGO elements to improve the way your robot moves. Will your robot walk, wiggle, hop, or slither? Will it move slower, faster or farther?
+* Click on the JavaScript tab and experiment with changing the values in the code.
+* Add a custom image or sounds by adding blocks from the Brick or Music menus.
+* Does your robot resemble a creature? Add arts and crafts materials to your project.
+
+## Communicate
+
+* Create a video of your project, especially your final presentation and your robot’s performance.
+* Explain some important features of your software program.
+* Produce a building guide for your model by taking a series of photographs as you deconstruct it.
+* Include an image of your program with comments.
+* Add a team photograph!
+
+Congratulations! What will you design next?

docs/design-engineering/make-it-smarter.md

@@ -0,0 +1,172 @@
+# Make It Smarter and Faster 
+
+## Connect 
+
+### Design Brief
+
+Design, build and program a robotic creature that can sense its environment and respond by moving.
+
+https://www.youtube.com/watch?v=y9-A_C_08KY
+
+* What do the robots in the video need to be able to sense, plan, and act?
+* What senses do humans have and why are they important to us?
+* How many human-like senses do you see the robots demonstrating? 
+
+### Brainstorm 
+
+Discuss different solutions to the design brief.
+
+Think about: 
+
+* What kind of creature can it be? 
+* How can it move? 
+* What does it need to be aware so that it stays safe, well fed and warm (or cool)? 
+* Is it looking for food, a safe place to hide or a warm place to soak up the sun? 
+* Will the creature need to move fast or slow? 
+* Will it need to turn? 
+* Will it need to go backward?
+
+![EV3 and bricks](/static/lessons/make-it-smarter/bricks.png)
+
+## Construct
+ 
+### Build
+
+Think about a creature’s movement for inspiration. Your mechanism can be attached or unattached to the EV3 brick. You can start by tinkering with the LEGO elements in the picture add then build on.
+
+More building ideas: 
+
+| | | | | |
+|-|-|-|-|-|
+|[![EV3 Frames](/static/lessons/make-it-smarter/ev3-parts-frames.jpg)][EV3 Frames] | |[![EV3 Color Sensor 1](/static/lessons/make-it-smarter/ev3-parts-color-sensor-1.jpg)][Color Sensor 1] | |[![EV3 Gyro Sensor](/static/lessons/make-it-smarter/ev3-parts-gyro-sensor.jpg)][Gyro Sensor] |
+| [EV3 Frames] | | [Color Sensor 1] | | [Gyro Sensor] |
+<br/>
+
+| | | | | |
+|-|-|-|-|-|
+|[![EV3 Ultrasonic Sensor](/static/lessons/make-it-smarter/ev3-parts-ultrasonic-sensor.jpg)][Ultrasonic Sensor] | | [![EV3 Touch Sensor](/static/lessons/make-it-smarter/ev3-parts-touch-sensor.jpg)][Touch Sensor] | | [![EV3 Gyro Sensor](/static/lessons/make-it-smarter/ev3-parts-jaw.jpg)][Jaw] |
+| [Ultrasonic Sensor] | | [Touch Sensor] | | [Jaw] |
+<br/>
+
+| | | | | |
+|-|-|-|-|-|
+| [![EV3 Leg 1](/static/lessons/make-it-smarter/ev3-parts-leg-1.jpg)][Leg 1] | | [![EV3 Leg 2](/static/lessons/make-it-smarter/ev3-parts-leg-2.jpg)][Leg 2] | | [![EV3 Leg 3](/static/lessons/make-it-smarter/ev3-parts-leg-3.jpg)][Leg 3] |
+| [Leg 1] | | [Leg 2] | | [Leg 3] |
+
+### Program 
+
+Before you program, think about:  
+
+* How will you program the robot to sense?
+* How will you program the robot to respond?
+* Which programming blocks will you use?
+
+### ~hint
+
+**Hint:** Explore the different Sensor blocks in the Sensors Menu
+
+### ~
+
+### Sample Solution 
+
+The Insect uses its Ultrasonic Sensor to sense danger and move away from a threat.
+
+https://www.youtube.com/watch?v=PoeYoiXHHE4
+<br/>
+The Insect solution combines these building ideas:
+
+* [EV3 Frames]
+* [Leg 2]
+* [Leg 3]
+* [Ultrasonic Sensor]
+
+Four copies of Leg 3 are built: one for the front left, one for the back right, and two mirror copies for the front right and back left.
+
+Building Instructions:
+
+[![Insect robot](/static/lessons/make-it-smarter/insect-bot.jpg)](https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/insect-94b8a46f0dc5082c9d78ddb734626dc9.pdf)
+
+### Sample Solution 
+
+This program checks if the Ultrasonic Sensor senses something near. 
+
+The blocks inside the ``||loops:forever||`` loop have these actions: 
+
+1. Turn on the ``green`` EV3 brick Status Light.
+2. Wait for Ultrasonic Sensor to detect an object.
+3. Turn on Motors ``A`` and ``D`` in opposite directions.
+4. Wait for one quarter of a second (``1500`` milli seconds).
+5. Reverse the direction of Motors ``A`` and ``D``.
+6. Wait for one quarter of a second.
+7. Stop all motors.
+8. Make an insect chirping sound.
+9. Loop continuously so that the insect wanders around when the Ultrasonic Sensor is detects something.
+
+```blocks
+forever(function () {
+    brick.setStatusLight(StatusLight.Green)
+    sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectDetected)
+    motors.largeAD.tank(50, -50)
+    pause(1500)
+    motors.largeAD.tank(-50, 50)
+    pause(1500)
+    motors.stopAll()
+    music.playSoundEffectUntilDone(sounds.animalsInsectChirp)
+})
+```
+
+### Download and test
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Contemplate 
+
+### Test and Analyze 
+
+As you work on your solution: 
+1. Describe one part of your design that worked especially well. 
+2. Describe one design change that you had to make. 
+3. What will you try next? 
+
+### Review and Revise 
+
+Take a moment to reflect on your robot solution. 
+
+Think about: 
+
+* Does your robot move when the sensor is activated? 
+* If not, what will you change to make the robot’s ability to sense and respond more obvious? 
+* What other behaviors can you add to the robot to make it more realistic? 
+
+Describe two ways you could improve your robot.
+
+## Continue 
+
+Personalize your project:
+
+* Add/remove LEGO elements to improve the way your robot moves. 
+* Click on the JavaScript tab and experiment with changing the values in the code.
+* Add a custom image or sounds by adding blocks from the Brick or Music menus.
+* Does your robot resemble a creature? Maybe add more craft materials to your project.
+
+## Communicate 
+
+Here are some ideas: 
+
+* Create a video of your project, especially your final presentation and your robot’s performance. Explain some important features of your software program. 
+* Produce a building guide for your model by taking a series of photographs as you deconstruct it. 
+* Include an image of your program with comments. 
+* Add a team photograph! 
+
+Congratulations! What will you design next?
+
+
+[EV3 Frames]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/ev3%20frames-5054ee378e624fb4cb31158d2fc8e5cf.pdf
+[Color Sensor 1]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/color%20sensor_v1-16a7231bdc187cd88a8da120c68f58d5.pdf
+[Gyro Sensor]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/gyro%20sensor-6f0fdbd82ae45fe0effa0ebf3f460f3d.pdf
+[Ultrasonic Sensor]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/ultrasonic%20sensor-a56156c72e8946ed4c58c5e69f3520d3.pdf
+[Touch Sensor]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/touch%20sensor-868fda1b9d6070a0a034fb22456a7fc9.pdf
+[Jaw]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/jaw-ee93e8f3243e4d30cd34b0c337c33653.pdf
+[Leg 1]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/leg%201-c14624046ea3a95148820ed404f5ac65.pdf
+[Leg 2]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/leg%202-8855c35b990205f6b9d7130687a3d4db.pdf
+[Leg 3]: https://le-www-live-s.legocdn.com/sc/media/files/support/mindstorms%20ev3/building-instructions/design%20engineering%20projects/leg%203-575d52ef15fb79f1e4d3350d36607160.pdf

docs/examples.md

@@ -2,6 +2,207 @@
 
 Here are some fun programs for your @boardname@!
 
+## Maker
+
+```codecard
+[
+{
+  "name": "Sound Of Color",
+  "description": "Play different sounds based on the color",
+  "url":"/maker/sound-of-color",
+  "cardType": "example",
+  "imageUrl": "/static/maker/sound-of-color.png"
+},
+{
+  "name": "Security Gadget",
+  "description": "Raise the alarm when your brick is lifted!",
+  "url":"/maker/security-gadget",
+  "cardType": "example",
+  "imageUrl": "/static/maker/security-gadget.png"
+},
+{
+  "name": "Movement Detector",
+  "description": "Raise the alarm when an movement sneaks in",
+  "url":"/maker/movement-detector",
+  "cardType": "example",
+  "imageUrl": "/static/maker/movement-detector.png"
+},
+{
+  "name": "Puppet",
+  "description": "Build an automated puppet",
+  "url":"/maker/puppet",
+  "cardType": "example",
+  "imageUrl": "/static/maker/puppet.png"
+}
+]
+```
+
+## Three Point Turn
+
+```codecard
+[
+{
+  "name": "Three Point Turn 1",
+  "description": "Activity 1",
+  "url":"/coding/three-point-turn-1",
+  "cardType": "example"
+}, {
+  "name": "Three Point Turn 2",
+  "description": "Activity 2",
+  "url":"/coding/three-point-turn-2",
+  "cardType": "example"
+}, {
+  "name": "Three Point Turn 3",
+  "description": "Activity 3",
+  "url":"/coding/three-point-turn-3",
+  "cardType": "example"
+}]
+```
+
+## Reversing the robot
+
+```codecard
+[{
+  "name": "Reversing the robot 1",
+  "description": "Activity 1",
+  "url":"/coding/reversing-the-robot-1",
+  "cardType": "example"
+}, {
+  "name": "Reversing the robot 2",
+  "description": "Activity 2",
+  "url":"/coding/reversing-the-robot-2",
+  "cardType": "example"
+}, {
+  "name": "Reversing the robot 3",
+  "description": "Activity 3",
+  "url":"/coding/reversing-the-robot-3",
+  "cardType": "example"
+}]
+```
+
+## Light the way
+
+```codecard
+[{
+  "name": "Light the way 1",
+  "description": "Activity 1",
+  "url":"/coding/light-the-way-1",
+  "cardType": "example"
+}, {
+  "name": "Light the way 2",
+  "description": "Activity 2",
+  "url":"/coding/light-the-way-2",
+  "cardType": "example"
+}, {
+  "name": "Light the way 3",
+  "description": "Activity 3",
+  "url":"/coding/light-the-way-3",
+  "cardType": "example"
+}    
+]
+```
+
+## Traffic Lights
+
+```codecard
+[{
+  "name": "Traffic Lights 1",
+  "description": "Activity 1",
+  "url":"/coding/traffic-lights-1",
+  "cardType": "example"
+}, {
+  "name": "Traffic Lights 2",
+  "description": "Activity 2",
+  "url":"/coding/traffic-lights-2",
+  "cardType": "example"
+}, {
+  "name": "Traffic Lights 3",
+  "description": "Activity 3",
+  "url":"/coding/traffic-lights-3",
+  "cardType": "example"
+}
+]
+```
+
+## Reverse Bepper
+
+```codecard
+[{
+  "name": "Reverse Beeper 1",
+  "description": "Activity 1",
+  "url":"/coding/reverse-beeper-1",
+  "cardType": "example"
+}, {
+  "name": "Reverse Beeper 2",
+  "description": "Activity 2",
+  "url":"/coding/reverse-beeper-2",
+  "cardType": "example"
+}, {
+  "name": "Reverse Beeper 3",
+  "description": "Activity 3",
+  "url":"/coding/reverse-beeper-3",
+  "cardType": "example"
+}]
+```
+
+## Ignition
+
+```codecard
+[{
+  "name": "Ignition 1",
+  "description": "Activity 1",
+  "url":"/coding/ingition-1",
+  "cardType": "example"
+}, {
+  "name": "Ignition 2",
+  "description": "Activity 2",
+  "url":"/coding/ignition-2",
+  "cardType": "example"
+}, {
+  "name": "Ignition 3",
+  "description": "Activity 3",
+  "url":"/coding/ignition-3",
+  "cardType": "example"
+}]
+```
+
+## Cruise Control
+
+```codecard
+[{
+  "name": "Cruise Control 1",
+  "description": "Activity 1",
+  "url":"/coding/cruise-control-1",
+  "cardType": "example"
+}, {
+  "name": "Cruise Control 2",
+  "description": "Activity 2",
+  "url":"/coding/cruise-control-2",
+  "cardType": "example"
+}, {
+  "name": "Cruise Control 3",
+  "description": "Activity 3",
+  "url":"/coding/cruise-control-3",
+  "cardType": "example"
+}]
+```
+
+## Roaming
+
+```codecard
+[{
+  "name": "Roaming 1",
+  "description": "Activity 1",
+  "url":"/coding/roaming-1",
+  "cardType": "example"
+}, {
+  "name": "Roaming 2",
+  "description": "Activity 2",
+  "url":"/coding/roaming-2",
+  "cardType": "example"
+}]
+```
+
 ## Fun stuff
 
 ```codecard
@@ -11,5 +212,10 @@ Here are some fun programs for your @boardname@!
   "description": "Keep your brick entertained and happy",
   "url":"/examples/happy-unhappy",
   "cardType": "example"
+}, {
+  "name": "Distance Measurer",
+  "description": "Use a motor to measure angle and distance",
+  "url": "/examples/distance-measurer",
+  "cardType": "example"
 }]
 ```

docs/examples/core-set/gyroboy-blocks.md

@@ -0,0 +1,178 @@
+# Gyroboy
+
+Work in progress
+
+```blocks
+let motorSpeed1 = 0
+let motorSpeed2 = 0
+let motorSpeed3 = 0
+let motorSpeed = 0
+let fallen = false
+let motorSpeed0 = 0
+let oldControlDrive = 0
+let controlDrive = 0
+let power = 0
+let motorAngle = 0
+let gyroAngle = 0
+let controlSteering = 0
+let state = 0
+let motorPosition = 0
+let temp = 0
+let gyroRate = 0
+let timestep = 0
+sensors.color1.onColorDetected(ColorSensorColor.Red, function () {
+    music.playTone(2000, 100)
+    controlDrive = 0
+    controlSteering = 0
+})
+// reads the motor angle and computes the motor speed,
+// position
+function computeMotors() {
+    temp = motorAngle
+    // read angle on both motors
+    motorAngle = motors.largeD.angle() + motors.largeA.angle()
+    // and estimate speed as angle difference
+    motorSpeed0 = motorAngle - temp
+    // average last 4 speed readings
+    motorSpeed = (motorSpeed0 + motorSpeed1 + motorSpeed2 + motorSpeed3) / 4 / timestep
+    // shift all previous recorded speeds by one
+    motorSpeed3 = motorSpeed2
+    motorSpeed2 = motorSpeed1
+    motorSpeed1 = motorSpeed0
+    // compute position from speed
+    motorPosition = motorPosition + timestep * motorSpeed
+}
+// read the gyro rate and computes the angle
+function computeGyro() {
+    gyroRate = sensors.gyro2.rate()
+    gyroAngle = gyroAngle + timestep * gyroRate
+}
+function reset() {
+    state = 0
+    // sleeping
+    moods.sleeping.show();
+    // reset counters
+    motors.largeA.reset()
+    motors.largeD.reset()
+    // motors are unregulated
+    motors.largeA.setRegulated(false)
+    motors.largeD.setRegulated(false)
+    // clear the gyro sensor to remove drift
+    sensors.gyro2.reset()
+    // fall detection timer
+    control.timer2.reset()
+    // timestep computation timer
+    control.timer3.reset()
+    motorAngle = 0
+    motorPosition = 0
+    motorSpeed = 0
+    motorSpeed0 = 0
+    motorSpeed1 = 0
+    motorSpeed2 = 0
+    motorSpeed3 = 0
+    gyroRate = 0
+    gyroAngle = 0
+    fallen = false
+    power = 0
+    controlSteering = 0
+    controlDrive = 0
+    // awake
+    moods.awake.show();
+    gyroAngle = -0.25
+    state = 1;
+}
+// compute set point for motor position and required
+// motor power
+function computePower() {
+    // apply control and compute desired motor position
+    motorPosition -= timestep * controlDrive;
+    // estimate power based on sensor readings and control
+    // values
+    power = 0.8 * gyroRate + 15 * gyroAngle + (0.08 * motorSpeed + 0.12 * motorPosition) - 0.01 * controlDrive
+    // ensure that power stays within -100, 100
+    if (power > 100) {
+        power = 100
+    } else if (power < -100) {
+        power = -100
+    }
+}
+// test if the robot has fallen off
+function checkFallen() {
+    if (Math.abs(power) < 100) {
+        control.timer2.reset()
+    }
+    if (control.timer2.seconds() > 2) {
+        fallen = true
+    }
+}
+// stop all motors and wait for touch button to be
+// pressed
+function stop() {
+    motors.stopAll()
+    state = 0
+    moods.knockedOut.show();
+    sensors.touch3.pauseUntil(ButtonEvent.Pressed)
+    moods.neutral.show();
+}
+sensors.ultrasonic4.onEvent(UltrasonicSensorEvent.ObjectNear, function () {
+    moods.dizzy.show()
+    controlSteering = 0
+    oldControlDrive = controlDrive
+    controlDrive = -10
+    motors.mediumC.run(30, 30, MoveUnit.Degrees);
+    motors.mediumC.run(-30, 60, MoveUnit.Degrees);
+    motors.mediumC.run(30, 30, MoveUnit.Degrees);
+    if (Math.randomRange(-1, 1) >= 1) {
+        controlSteering = 70
+    } else {
+        controlSteering = -70
+    }
+    pause(4000)
+    music.playTone(2000, 100)
+    controlSteering = 0
+    controlDrive = oldControlDrive
+    moods.neutral.show()
+})
+// compute the elapsed time since the last iteration
+function computeTimestep() {
+    timestep = control.timer3.seconds()
+    control.timer3.reset()
+}
+sensors.color1.onColorDetected(ColorSensorColor.Green, function () {
+    moods.winking.show()
+    controlDrive = 150
+    controlSteering = 0
+})
+sensors.color1.onColorDetected(ColorSensorColor.Blue, function () {
+    moods.middleRight.show()
+    controlSteering = 70
+})
+// apply power to motors
+function controlMotors() {
+    motors.largeA.run(power + controlSteering * 0.1)
+    motors.largeD.run(power - controlSteering * 0.1)
+}
+sensors.color1.onColorDetected(ColorSensorColor.Yellow, function () {
+    moods.middleLeft.show()
+    controlSteering = -70
+})
+sensors.color1.onColorDetected(ColorSensorColor.White, function () {
+    moods.sad.show();
+    controlDrive = -75
+})
+timestep = 0.014
+// main loop
+forever(function () {
+    reset()
+    while (!fallen) {
+        control.timer3.pauseUntil(5)
+        computeTimestep()
+        computeGyro()
+        computeMotors()
+        computePower()
+        controlMotors()
+        checkFallen()
+    }
+    stop()
+})
+```

docs/examples/core-set/gyroboy-labview.md

@@ -0,0 +1,215 @@
+# Gyroboy LabView
+
+```typescript
+let mSum = 0;
+let mPos = 0;
+let mSpd = 0;
+let mD = 0;
+let mDP1 = 0;
+let mDP2 = 0;
+let mDP3 = 0;
+let Crdv = 0;
+let cLo = 0;
+let gAng = 0;
+let ok = false;
+let pwr = 0;
+let Cstr = 0;
+let Cdrv = 0;
+let gMn = 0;
+let gMx = 0;
+let gSum = 0;
+let gyro = 0;
+let gOS = 0;
+let gSpd = 0;
+let tInt = 0.014;
+let lpwr = 0
+let rpwr = 0
+let tStart = 0
+let st = 0
+let oldDr = 0
+
+function RST() {
+    motors.largeA.reset()
+    motors.largeD.reset()
+    motors.largeA.setRegulated(false)
+    motors.largeD.setRegulated(false)
+    sensors.gyro2.reset()
+    sensors.gyro2.rate()
+    control.timer2.reset()
+    pause(5000)
+    mSum = 0;
+    mPos = 0;
+    mD = 0;
+    mDP1 = 0;
+    mDP2 = 0;
+    mDP3 = 0;
+    Crdv = 0;
+    cLo = 0;
+    gAng = 0;
+    ok = false;
+    pwr = 0;
+    st = 0;
+    Cstr = 0;
+    Cdrv = 0;
+}
+
+function OS() {
+    // OSL
+    do {
+        gMn = 1000;
+        gMx = -100;
+        gSum = 0;
+        // gChk
+        for (let i = 0; i < 200; i++) {
+            gyro = sensors.gyro2.rate()
+            gSum = gyro;
+            gMx = Math.max(gMx, gyro)
+            gMn = Math.min(gMn, gyro)
+            pause(4);
+        }
+    } while (gMx - gMn > 2);
+    gOS = gSum / 200;
+}
+
+function GT() {
+    if (cLo == 0) {
+        tInt = 0.014;
+        control.timer1.reset();
+    } else {
+        tInt = control.timer1.seconds() / cLo;
+    }
+    cLo++;
+}
+
+function GG() {
+    gyro = sensors.gyro2.rate();
+    gOS = 0.0005 * gyro + (1 - 0.0005) * gOS
+    gSpd = gyro - gOS;
+    gAng = gAng + tInt * gSpd;
+}
+
+function GM() {
+    let temp = mSum
+    mSum = motors.largeD.angle() + motors.largeA.angle();
+    mD = mSum - temp;
+    mPos = mPos + mD;
+    mSpd = ((mDP1 + mDP2 + mDP3 + mD) / 4) / tInt;
+    mDP3 = mDP2;
+    mDP2 = mDP1;
+    mDP1 = mD;
+}
+
+function EQ() {
+    mPos = mPos - Cdrv * tInt;
+    pwr = (0.8 * gSpd + 15 * gAng) + (0.08 * mSpd + 0.12 * mPos) - 0.01 * Cdrv
+    if (pwr > 100) pwr = 100
+    else if (pwr < -100) pwr = -100
+}
+
+function cntrl() {
+    mPos = mPos - tInt * Cdrv
+    lpwr = (pwr + Cstr * 0.1)
+    rpwr = (pwr - Cstr * 0.1)
+}
+
+function CHK() {
+    if (Math.abs(pwr) < 100)
+        control.timer2.reset();
+    if (control.timer2.seconds() > 2) {
+        ok = true;
+    }
+}
+
+// M
+forever(function () {
+    RST();
+    brick.showImage(images.eyesSleeping)
+    OS()
+    gAng = -0.25;
+    music.playSoundEffect(sounds.movementsSpeedUp)
+    brick.showImage(images.eyesAwake)
+    st = 1;
+    // BALANCE
+    while (!ok) {
+        GT();
+        let t1 = control.timer1.millis()
+        GG();
+        GM();
+        EQ();
+        cntrl();
+        motors.largeA.run(lpwr)
+        motors.largeD.run(rpwr)
+        CHK()
+        let t2 = control.timer1.millis();
+        let p = 5 - (t2 - t1);
+        pause(Math.max(1, p))
+    }
+    motors.stopAll()
+    st = 0;
+    brick.setStatusLight(StatusLight.RedPulse);
+    brick.showImage(images.eyesKnockedOut)
+    music.playSoundEffect(sounds.movementsSpeedDown)
+    sensors.touch3.pauseUntil(ButtonEvent.Pressed)
+    brick.setStatusLight(StatusLight.Off);
+})
+
+// BHV
+forever(function () {
+    switch (st) {
+        case 0:
+            Cdrv = 0;
+            Cstr = 0;
+            break;
+        case 1:
+            Cdrv = 40;
+            pause(4000);
+            Cdrv = 0;
+            music.playTone(1000, 100);
+            st = 2;
+            break;
+        case 2:
+            switch (sensors.color1.color()) {
+                case ColorSensorColor.Red:
+                    music.playTone(2000, 100);
+                    Cdrv = 0;
+                    Cstr = 0;
+                    break;
+                case ColorSensorColor.Green:
+                    music.playTone(2000, 100);
+                    Cdrv = 150;
+                    Cstr = 0;
+                    break;
+                case ColorSensorColor.Blue:
+                    music.playTone(2000, 100);
+                    Cstr = 70;
+                    break;
+                case ColorSensorColor.Yellow:
+                    music.playTone(2000, 100);
+                    Cstr = -70;
+                    break;
+                case ColorSensorColor.White:
+                    music.playTone(2000, 100);
+                    Cdrv = -75;
+                    break;
+            }
+            if (sensors.ultrasonic4.distance() < 25) {
+                Cstr = 0;
+                oldDr = Cdrv;
+                Cdrv = -10;
+                motors.mediumC.run(30, 30, MoveUnit.Degrees);
+                motors.mediumC.run(-30, 60, MoveUnit.Degrees);
+                motors.mediumC.run(30, 30, MoveUnit.Degrees);
+                if (Math.randomRange(-1, 1) >= 1)
+                    Cstr = 70;
+                else
+                    Cstr = -70;
+                pause(4000);
+                music.playTone(2000, 100)
+                Cstr = 0;
+                Cdrv = oldDr;
+            }
+            break;
+    }
+    pause(80);
+})
+```

docs/examples/core-set/puppy-labview.md

@@ -0,0 +1,390 @@
+# Puppy
+
+```typescript
+let P_T = 0;
+let ISS = 0;
+let F_T = 0;
+let P_C = 0;
+let F_C = 0;
+let DB_S = 0;
+let NS = false;
+let IBP = 0;
+let IAP = 0;
+let C = false;
+let TC = false;
+let OTC = false;
+let COL = 0;
+let OCOL = 0;
+let _C = false;
+let GTO = 0;
+
+function DN() {
+    motors.largeAD.setBrake(true);
+    motors.largeAD.tank(50, 50, 1, MoveUnit.Seconds);
+    pause(100);
+    motors.largeA.clearCounts()
+    motors.largeD.clearCounts()
+}
+
+function MNRH() {
+    motors.mediumC.setBrake(true)
+    brick.showImage(images.legoEv3icon)
+    brick.setStatusLight(StatusLight.OrangePulse)
+    while (!brick.buttonEnter.wasPressed()) {
+        if (brick.buttonUp.wasPressed()) {
+            motors.mediumC.run(-100);
+        } else if (brick.buttonDown.wasPressed()) {
+            motors.mediumC.run(100);
+        } else {
+            motors.mediumC.stop();
+        }
+    }
+    motors.mediumC.stop();
+    motors.mediumC.clearCounts();
+    brick.setStatusLight(StatusLight.Green);
+}
+
+function IS(t: number) {
+    ISS = t;
+    switch (t) {
+        case 0:
+            brick.showImage(images.eyesNeutral);
+            break;
+        case 1:
+            brick.showImage(images.eyesSleeping);
+            break;
+        case 2:
+            brick.showImage(images.eyesTear);
+            // draw rect...
+            break;
+        case 3:
+            brick.showImage(images.eyesHurt);
+            break;
+        case 4:
+            brick.showImage(images.eyesAngry);
+            break;
+        case 5:
+            brick.showImage(images.eyesTiredMiddle);
+            break;
+        case 6:
+            brick.showImage(images.eyesTiredRight);
+            break;
+        case 7:
+            brick.showImage(images.eyesTiredLeft);
+            break;
+        case 8:
+            brick.showImage(images.eyesLove);
+            break;
+    }
+
+}
+
+function UP() {
+    if (motors.largeA.angle() > -50) {
+        control.runInParallel(function () {
+            motors.largeD.clearCounts()
+            motors.largeD.run(-35);
+            pauseUntil(() => motors.largeD.angle() < -25);
+            motors.largeD.stop();
+            motors.largeD.setRegulated(false)
+            motors.largeD.run(-15)
+            pauseUntil(() => motors.largeD.angle() < -65);
+            motors.largeD.stop();
+        })
+        motors.largeA.clearCounts()
+        motors.largeA.run(-35);
+        pauseUntil(() => motors.largeA.angle() < -25);
+        motors.largeA.stop();
+        motors.largeA.setRegulated(false)
+        motors.largeA.run(-15)
+        pauseUntil(() => motors.largeA.angle() < -65);
+        motors.largeA.stop();
+
+        pause(500);
+    }
+}
+
+function RST() {
+    P_T = Math.randomRange(3, 6);
+    F_T = Math.randomRange(2, 4);
+    P_C = 1;
+    F_C = 1;
+    control.timer1.reset();
+    control.timer2.reset();
+    control.timer3.reset();
+    CS(0);
+}
+
+function CS(db: number) {
+    if (DB_S != db) {
+        DB_S = db;
+        NS = true;
+    }
+}
+
+function MON() {
+    if (control.timer2.seconds() > 10) {
+        control.timer2.reset();
+        P_C--;
+        if (P_C < 0) {
+            P_C = 0;
+        }
+    }
+    if (control.timer1.seconds() > 20) {
+        control.timer1.reset()
+        F_C--;
+        if (F_C < 0) {
+            F_C = 0;
+        }
+    }
+    if (control.timer3.seconds() > 30) {
+        control.timer3.reset();
+        CS(1);
+    }
+}
+
+function UIS() {
+    if (control.timer5.seconds() > IBP) {
+        control.timer5.reset();
+        if (ISS == 1) {
+            ISS = 6;
+            IBP = Math.randomRange(1, 5);
+        } else {
+            ISS = 1;
+            IBP = 0.25;
+        }
+        IS(ISS);
+    }
+    if (control.timer6.seconds() > IAP) {
+        if (ISS != 1) {
+            control.timer6.reset();
+            IAP = Math.randomRange(1, 10)
+            if (ISS != 7) {
+                ISS = 7
+            } else {
+                ISS = 6;
+            }
+            IS(ISS);
+        }
+    }
+}
+
+function UPDB() {
+    if ((P_T == P_C) && (F_T == F_C)) {
+        CS(6);
+    }
+    if ((P_T > P_C) && (F_T < F_C)) {
+        CS(3);
+    }
+    if ((P_T < P_C) && (F_T > F_C)) {
+        CS(5);
+    }
+    if ((P_C == 0) && (F_C > 0)) {
+        CS(2)
+    }
+    if (F_C == 0) {
+        CS(4)
+    }
+}
+
+function PTC() {
+    C = false;
+    OTC = TC;
+    TC = sensors.touch1.isPressed()
+    if (TC != OTC && TC) {
+        P_C++;
+        control.timer3.reset();
+        if (DB_S != 4) {
+            IS(2);
+            music.playSoundEffect(sounds.animalsDogSniff);
+            C = true;
+        }
+    }
+    return C;
+}
+
+function FDC() {
+    OCOL = COL;
+    COL = sensors.color4.color();
+    _C = false;
+    if ((COL != 0) && (OCOL != COL)) {
+        F_C++;
+        _C = true;
+        control.timer3.reset();
+        IS(2);
+        music.playSoundEffect(sounds.expressionsCrunching)
+    }
+    return _C;
+}
+
+function IDL() {
+    if (NS) {
+        NS = false;
+        UP();
+    }
+    UIS();
+    UPDB();
+    PTC();
+    FDC();
+}
+
+function MHT(Pos: number) {
+    let _R = Pos - motors.mediumC.angle();
+    if (_R >= 0) {
+        motors.mediumC.run(100, _R, MoveUnit.Degrees);
+    } else {
+        motors.mediumC.run(-100, Math.abs(_R), MoveUnit.Degrees);
+    }
+}
+
+function SLP() {
+    if (NS) {
+        NS = false;
+        IS(5)
+        DN()
+        MHT(3000)
+        IS(1)
+        music.playSoundEffect(sounds.expressionsSnoring)
+    }
+    if (sensors.touch1.isPressed() || brick.buttonEnter.isPressed()) {
+        music.stopAllSounds();
+        control.timer3.reset();
+        CS(7);
+    }
+}
+
+function PLF() {
+    if (NS) {
+        NS = false
+        IS(0)
+        UP()
+        music.playSoundEffect(sounds.animalsDogBark2)
+        control.timer4.reset()
+        GTO = Math.randomRange(4, 8);
+    }
+    if(PTC()) {
+        CS(0);
+    }
+    if (control.timer4.seconds() > GTO) {
+        music.playSoundEffect(sounds.animalsDogBark2)
+        control.timer4.reset();
+        GTO = Math.randomRange(4, 8);
+    }
+}
+
+function NGR() {
+    NS = false
+    IS(4)
+    music.playSoundEffect(sounds.animalsDogGrowl);
+    UP();
+    pause(1500);
+    music.stopAllSounds()
+    music.playSoundEffect(sounds.animalsDogBark1)
+    P_C--;
+    CS(0);
+}
+
+function HNG() {
+    if (NS) {
+        NS = false;
+        IS(3)
+        DN();
+        music.playSoundEffect(sounds.animalsDogWhine);        
+    }
+    if(FDC()) {
+        CS(0)
+    }
+    if (PTC()) {
+        CS(3);
+    }
+}
+
+function PPP() {
+    NS = false;
+    IS(2);
+    UP();
+    pause(100)
+    motors.largeA.run(-30, 70, MoveUnit.Degrees);
+    pause(800);
+    music.playSoundEffect(sounds.mechanicalHorn1);
+    pause(1000);
+    for(let i = 0; i < 3; ++i) {
+        motors.largeA.run(-30, 20, MoveUnit.Degrees);
+        motors.largeA.run(30, 20, MoveUnit.Degrees);
+    }
+    motors.largeA.run(30, 70, MoveUnit.Degrees);
+    F_C = 1;
+    CS(0);
+}
+
+function HPY() {
+    IS(8)
+    MHT(0);
+    motors.largeAD.run(10, 0.8, MoveUnit.Seconds);
+    for(let i = 0; i < 3; ++i) {
+        music.playSoundEffect(sounds.animalsDogBark1);
+        motors.largeAD.run(-100, 0.2, MoveUnit.Seconds);
+        pause(300)
+        motors.largeAD.run(10, 0.3, MoveUnit.Seconds)
+    }
+    pause(500);
+    music.stopAllSounds();
+    DN();
+    RST();
+}
+
+function STL() {
+    UP();
+    motors.largeAD.run(-20, 60, MoveUnit.Degrees);
+    music.playSoundEffect(sounds.animalsDogWhine);
+    motors.largeAD.run(20, 60, MoveUnit.Degrees);
+}
+
+function WKU() {
+    let stateC = false;
+    IS(5);
+    music.playSoundEffect(sounds.animalsDogWhine)
+    MHT(0)
+    DN()
+    STL()
+    pause(1000);
+    UP()
+    CS(0;)
+}
+
+DN();
+MNRH();
+// compare button state???
+IS(1);
+UP();
+RST();
+forever(function () {
+    MON();
+    switch (DB_S) {
+        case 0:
+            IDL();
+            break;
+        case 1:
+            SLP();
+            break;
+        case 2:
+            PLF();
+            break;
+        case 3:
+            NGR();
+            break;
+        case 4:
+            HNG();
+            break;
+        case 5:
+            PPP();
+            break;
+        case 6:
+            HPY();
+            break;
+        case 7:
+            WKU();
+            break;
+    }
+})
+```

docs/examples/core-set/robotarm-labview.md

@@ -0,0 +1,51 @@
+# Robot Arm
+
+```typescript
+function INI() {
+    motors.largeB.setBrake(true)
+    motors.largeC.setBrake(true)
+    motors.mediumA.setBrake(true)
+    motors.largeB.run(-50)
+    pauseUntil(() => sensors.color3.light(LightIntensityMode.Reflected) > 25);
+    motors.largeB.stop();
+    motors.mediumA.run(30, 1, MoveUnit.Seconds);
+    motors.mediumA.run(-50, 90, MoveUnit.Degrees);
+    motors.largeC.run(50)
+    sensors.touch1.pauseUntil(ButtonEvent.Pressed);
+    motors.largeC.run(-50, 0.86, MoveUnit.Rotations);
+}
+
+INI()
+
+let down = false;
+forever(function () {
+    brick.showImage(images.informationQuestionMark)
+    brick.setStatusLight(StatusLight.OrangePulse);
+    pauseUntil(() => (down = brick.buttonDown.wasPressed()) || brick.buttonUp.wasPressed())
+    brick.setStatusLight(StatusLight.Off)
+    music.playSoundEffect(sounds.mechanicalAirRelease)
+    brick.showImage(images.informationAccept)
+    if (down) {
+        brick.showImage(images.informationForward)
+        motors.largeC.run(65, 0.85, MoveUnit.Rotations);
+    } else {
+        brick.showImage(images.informationBackward)
+        motors.largeC.run(-65, 0.85, MoveUnit.Rotations);
+    }
+    motors.largeB.run(20, 275, MoveUnit.Degrees)
+    motors.mediumA.run(30, 1, MoveUnit.Seconds)
+    motors.largeB.run(-55)
+    pauseUntil(() => sensors.color3.light(LightIntensityMode.Reflected) > 25);
+    motors.largeB.stop();
+    if (down) {
+        motors.largeC.run(-65, 0.86, MoveUnit.Rotations);
+    } else {
+        motors.largeC.run(65, 0.85, MoveUnit.Rotations);
+    }
+    motors.largeB.run(20, 275, MoveUnit.Degrees);
+    motors.mediumA.run(-30, 90, MoveUnit.Degrees);
+    motors.largeB.run(-55)
+    pauseUntil(() => sensors.color3.light(LightIntensityMode.Reflected) > 25);
+    motors.largeB.stop()
+})
+```

docs/examples/crane-labview.md

@@ -0,0 +1,51 @@
+# Crane LabView
+
+```blocks
+function INI() {
+    motors.largeB.setBrake(true)
+    motors.largeC.setBrake(true)
+    motors.mediumA.setBrake(true)
+    motors.largeB.run(-50)
+    pauseUntil(() => sensors.color3.light(LightIntensityMode.Reflected) > 25);
+    motors.largeB.stop();
+    motors.mediumA.run(30, 1, MoveUnit.Seconds);
+    motors.mediumA.run(-50, 90, MoveUnit.Degrees);
+    motors.largeC.run(50)
+    sensors.touch1.pauseUntil(ButtonEvent.Pressed);
+    motors.largeC.run(-50, 0.86, MoveUnit.Rotations);
+}
+
+INI()
+
+let down = false;
+forever(function () {
+    brick.showImage(images.informationQuestionMark)
+    brick.setStatusLight(StatusLight.OrangePulse);
+    pauseUntil(() => (down = brick.buttonDown.wasPressed()) || brick.buttonUp.wasPressed())
+    brick.setStatusLight(StatusLight.Off)
+    music.playSoundEffect(sounds.mechanicalAirRelease)
+    brick.showImage(images.informationAccept)
+    if (down) {
+        brick.showImage(images.informationForward)
+        motors.largeC.run(65, 0.85, MoveUnit.Rotations);
+    } else {
+        brick.showImage(images.informationBackward)
+        motors.largeC.run(-65, 0.85, MoveUnit.Rotations);
+    }
+    motors.largeB.run(20, 275, MoveUnit.Degrees)
+    motors.mediumA.run(30, 1, MoveUnit.Seconds)
+    motors.largeB.run(-55)
+    pauseUntil(() => sensors.color3.light(LightIntensityMode.Reflected) > 25);
+    motors.largeB.stop();
+    if (down) {
+        motors.largeC.run(-65, 0.86, MoveUnit.Rotations);
+    } else {
+        motors.largeC.run(65, 0.85, MoveUnit.Rotations);
+    }
+    motors.largeB.run(20, 275, MoveUnit.Degrees);
+    motors.mediumA.run(-30, 90, MoveUnit.Degrees);
+    motors.largeB.run(-55)
+    pauseUntil(() => sensors.color3.light(LightIntensityMode.Reflected) > 25);
+    motors.largeB.stop()
+})
+```

docs/examples/distance-measurer.md

@@ -0,0 +1,34 @@
+# Distance Measurer
+
+```blocks
+let distance = 0
+let angle = 0
+let measuring = false
+let radius = 0
+// Start and stop measuring with the enter button
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    if (measuring) {
+        // turn off the measuring
+        measuring = false
+        brick.setStatusLight(StatusLight.Off)
+    } else {
+        // turn on the measuring clear the counters so that
+        // the motor tracks the angle
+        measuring = true
+        motors.largeB.clearCounts()
+        brick.setStatusLight(StatusLight.GreenPulse)
+    }
+})
+radius = 2.5
+brick.showString("Press ENTER to measure", 4)
+forever(function () {
+    if (measuring) {
+        angle = motors.largeB.angle()
+        distance = angle / 180 * Math.PI * radius
+        brick.clearScreen()
+        brick.showValue("angle", angle, 2)
+        brick.showValue("distance", distance, 3)
+    }
+    pause(100)
+})
+```

docs/examples/gyro-boy-labview.md

@@ -0,0 +1,215 @@
+# Gyro Boy LabView
+
+```blocks
+let mSum = 0;
+let mPos = 0;
+let mSpd = 0;
+let mD = 0;
+let mDP1 = 0;
+let mDP2 = 0;
+let mDP3 = 0;
+let Crdv = 0;
+let cLo = 0;
+let gAng = 0;
+let ok = false;
+let pwr = 0;
+let Cstr = 0;
+let Cdrv = 0;
+let gMn = 0;
+let gMx = 0;
+let gSum = 0;
+let gyro = 0;
+let gOS = 0;
+let gSpd = 0;
+let tInt = 0.014;
+let lpwr = 0
+let rpwr = 0
+let tStart = 0
+let st = 0
+let oldDr = 0
+
+function RST() {
+    motors.largeA.reset()
+    motors.largeD.reset()
+    motors.largeA.setRegulated(false)
+    motors.largeD.setRegulated(false)
+    sensors.gyro2.reset()
+    sensors.gyro2.rate()
+    control.timer2.reset()
+    pause(5000)
+    mSum = 0;
+    mPos = 0;
+    mD = 0;
+    mDP1 = 0;
+    mDP2 = 0;
+    mDP3 = 0;
+    Crdv = 0;
+    cLo = 0;
+    gAng = 0;
+    ok = false;
+    pwr = 0;
+    st = 0;
+    Cstr = 0;
+    Cdrv = 0;
+}
+
+function OS() {
+    // OSL
+    do {
+        gMn = 1000;
+        gMx = -100;
+        gSum = 0;
+        // gChk
+        for (let i = 0; i < 200; i++) {
+            gyro = sensors.gyro2.rate()
+            gSum = gyro;
+            gMx = Math.max(gMx, gyro)
+            gMn = Math.min(gMn, gyro)
+            pause(4);
+        }
+    } while (gMx - gMn > 2);
+    gOS = gSum / 200;
+}
+
+function GT() {
+    if (cLo == 0) {
+        tInt = 0.014;
+        control.timer1.reset();
+    } else {
+        tInt = control.timer1.seconds() / cLo;
+    }
+    cLo++;
+}
+
+function GG() {
+    gyro = sensors.gyro2.rate();
+    gOS = 0.0005 * gyro + (1 - 0.0005) * gOS
+    gSpd = gyro - gOS;
+    gAng = gAng + tInt * gSpd;
+}
+
+function GM() {
+    let temp = mSum
+    mSum = motors.largeD.angle() + motors.largeA.angle();
+    mD = mSum - temp;
+    mPos = mPos + mD;
+    mSpd = ((mDP1 + mDP2 + mDP3 + mD) / 4) / tInt;
+    mDP3 = mDP2;
+    mDP2 = mDP1;
+    mDP1 = mD;
+}
+
+function EQ() {
+    mPos = mPos - Cdrv * tInt;
+    pwr = (0.8 * gSpd + 15 * gAng) + (0.095 * mSpd + 0.13 * mPos) - 0.01 * Cdrv
+    if (pwr > 100) pwr = 100
+    else if (pwr < -100) pwr = -100
+}
+
+function cntrl() {
+    mPos = mPos - tInt * Cdrv
+    lpwr = (pwr + Cstr * 0.1)
+    rpwr = (pwr - Cstr * 0.1)
+}
+
+function CHK() {
+    if (Math.abs(pwr) < 100)
+        control.timer2.reset();
+    if (control.timer2.seconds() > 2) {
+        ok = true;
+    }
+}
+
+// M
+forever(function () {
+    RST();
+    brick.showImage(images.eyesSleeping)
+    OS()
+    gAng = -0.25;
+    music.playSoundEffect(sounds.movementsSpeedUp)
+    brick.showImage(images.eyesAwake)
+    st = 1;
+    // BALANCE
+    while (!ok) {
+        GT();
+        let t1 = control.timer1.millis()
+        GG();
+        GM();
+        EQ();
+        cntrl();
+        motors.largeA.run(lpwr)
+        motors.largeD.run(rpwr)
+        CHK()
+        let t2 = control.timer1.millis();
+        let p = 5 - (t2 - t1);
+        pause(Math.max(1, p))
+    }
+    motors.stopAll()
+    st = 0;
+    brick.setStatusLight(StatusLight.RedPulse);
+    brick.showImage(images.eyesKnockedOut)
+    music.playSoundEffect(sounds.movementsSpeedDown)
+    sensors.touch3.pauseUntil(ButtonEvent.Pressed)
+    brick.setStatusLight(StatusLight.Off);
+})
+
+// BHV
+forever(function () {
+    switch (st) {
+        case 0:
+            Cdrv = 0;
+            Cstr = 0;
+            break;
+        case 1:
+            Cdrv = 40;
+            pause(4000);
+            Cdrv = 0;
+            music.playTone(1000, 100);
+            st = 2;
+            break;
+        case 2:
+            switch (sensors.color1.color()) {
+                case ColorSensorColor.Red:
+                    music.playTone(2000, 100);
+                    Cdrv = 0;
+                    Cstr = 0;
+                    break;
+                case ColorSensorColor.Green:
+                    music.playTone(2000, 100);
+                    Cdrv = 150;
+                    Cstr = 0;
+                    break;
+                case ColorSensorColor.Blue:
+                    music.playTone(2000, 100);
+                    Cstr = 70;
+                    break;
+                case ColorSensorColor.Yellow:
+                    music.playTone(2000, 100);
+                    Cstr = -70;
+                    break;
+                case ColorSensorColor.White:
+                    music.playTone(2000, 100);
+                    Cdrv = -75;
+                    break;
+            }
+            if (sensors.ultrasonic4.distance() < 25) {
+                Cstr = 0;
+                oldDr = Cdrv;
+                Cdrv = -10;
+                motors.mediumC.run(30, 30, MoveUnit.Degrees);
+                motors.mediumC.run(-30, 60, MoveUnit.Degrees);
+                motors.mediumC.run(30, 30, MoveUnit.Degrees);
+                if (Math.randomRange(-1, 1) >= 1)
+                    Cstr = 70;
+                else
+                    Cstr = -70;
+                pause(4000);
+                music.playTone(2000, 100)
+                Cstr = 0;
+                Cdrv = oldDr;
+            }
+            break;
+    }
+    pause(80);
+})
+```

docs/examples/happy-unhappy.md

@@ -3,10 +3,10 @@
 Use a touch sensor to make the brick happy.
 
 ```blocks
-sensors.touchSensor1.onEvent(TouchSensorEvent.Pressed, function () {
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
     brick.showImage(images.expressionsBigSmile)
 })
-sensors.touchSensor1.onEvent(TouchSensorEvent.Released, function () {
+sensors.touch1.onEvent(ButtonEvent.Released, function () {
     brick.showImage(images.expressionsSick)
 })
 ```

docs/examples/line-follower-pid.md

@@ -0,0 +1,50 @@
+# Gradien follower PID + calibration
+
+```blocks
+let lasterror = 0
+let D = 0
+let I = 0
+let P = 0
+let error = 0
+let setpoint = 0
+let max = 0
+let min = 0
+let v = 0
+v = sensors.color3.light(LightIntensityMode.Reflected)
+min = v
+max = v
+setpoint = v
+while (!(brick.buttonEnter.isPressed())) {
+    brick.clearScreen()
+    brick.showString("Move robot on terrain", 1)
+    brick.showString("Press ENTER when done", 2)
+    v = sensors.color3.light(LightIntensityMode.Reflected)
+    min = Math.min(min, v)
+    max = Math.max(max, v)
+    setpoint = (max + min) / 2
+    brick.showValue("v", v, 3)
+    brick.showValue("min", min, 4)
+    brick.showValue("max", v, 5)
+    brick.showValue("setpoint", setpoint, 6)
+    pause(100)
+}
+forever(function () {
+    brick.clearScreen()
+    v = sensors.color3.light(LightIntensityMode.Reflected)
+    brick.showValue("light", v, 1)
+    error = v - setpoint
+    brick.showValue("error", error, 2)
+    P = error * 5
+    brick.showValue("P", P, 3)
+    I = I + error * 0.01
+    brick.showValue("I", I, 4)
+    D = (error - lasterror) * 0.2
+    brick.showValue("D", D, 5)
+    motors.largeBC.steer(P + (I + D), 100)
+    lasterror = error
+    if (brick.buttonEnter.wasPressed()) {
+        motors.largeBC.run(0)
+        brick.buttonDown.pauseUntil(ButtonEvent.Bumped)
+    }
+})
+```

docs/getting-started.md

@@ -0,0 +1,22 @@
+# Getting Started
+
+## Projects
+
+```codecard
+[
+{
+    "name": "Try",
+    "imageUrl": "/static/lessons/try.png",
+    "description": "Get a quick introduction to programming.",
+    "url": "/getting-started/try",
+    "cardType": "side"
+},
+{
+    "name": "Use",
+    "imageUrl": "/static/lessons/use.png",
+    "description": "Build a robot and drive into the world of robotics!",
+    "url": "/getting-started/use",
+    "cardType": "side"
+}
+]
+```

docs/getting-started/try.md

@@ -0,0 +1,165 @@
+# Try 
+
+Get a quick introduction to programming with EV3.
+
+![Display on EV3 Brick with Music Notes](/static/getting-started/01_EyesOn_Intro.png)
+
+We are excited to help you get started with @boardname@. In this project we will guide you through connecting your EV3 brick, creating your first program, controlling a Large Motor, a Touch Sensor and a Color Sensor. These steps can take up to 45 minutes.
+
+## Turn on your EV3 Brick
+
+Power on your EV3 Brick by pressing the Center Button.
+
+![Hand pressing power button](/static/getting-started/02_PowerOn.png)
+
+## Connect Your EV3 Brick to Your Device
+
+Use the USB cable to connect your EV3 Brick to your device.
+
+![Computer and cable connected to EV3 Brick](/static/getting-started/03_insert-usb-02.png)
+
+## Create and Run your First Program
+
+**Code it:** Create the program shown here.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    brick.showMood(moods.neutral)
+    music.playSoundEffect(sounds.communicationHello)
+})
+```
+
+* Drag out a ``||brick:on button||`` block from Buttons section in the ``||brick:Brick||`` Toolbox drawer.
+* Drag a Brick Screen ``||brick:show mood||`` block inside the ``||brick:on button||`` block.
+* Change mood to ``neutral``.
+
+```block
+brick.showMood(moods.neutral)
+```
+
+* Drag a Music ``||music:play sound effect||`` block below the ``||brick:show mood||`` block.
+* Change sound effect to ``communication hello``.
+
+```block
+music.playSoundEffect(sounds.communicationHello)
+```
+
+**Download:** Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Did It Work?
+
+![EV3 Brick with eyes on the display](/static/getting-started/05_EyesOn.png)
+
+Verify that the program you just created shows eyes on the Brick Display, and that the EV3 Brick played the sound “Hello!”
+
+**Well done!**
+
+## Connect a Large Motor
+
+Now you will learn to control the Large Motor.
+
+![EV3 Brick with hands connecting Large Motor to Port D](/static/getting-started/06_PlugInLargeMotor.png)
+
+Connect a Large Motor to **Port D** of your EV3 Brick using any of the connector cables.
+
+## Create and Run This Program
+
+**Code it:** Create the program shown here.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeD.run(50, 1, MoveUnit.Rotations)
+})
+```
+
+* Start a new program.
+* Drag a ``||motors:run large A motor||`` block inside the ``||brick:on button||`` block.
+* Change ``large motor A`` to ``large motor D``.
+* Click on the **(+)** sign.
+* Change to ``1`` rotation.
+
+**Download:** Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Did It Rotate?
+
+Confirm that your motor has turned one rotation at power level 50 before stopping.
+
+![Large Motor D w/Rotating “WHRRR,” Hand, EV3 Brick](/static/getting-started/08_WorkingLargeMotor.png)
+
+Download and run the program as many times as you want in order to verify this, or tinker with different power levels and different rotations.
+
+## Connect a Touch Sensor
+
+We will now control the Large Motor using a Touch Sensor.
+
+![Hands connecting Touch Sensor to Port 1 on EV3 Brick](/static/getting-started/09_Connect_Touch.png)
+
+Keeping the Large Motor connected to **Port D**, connect a Touch Sensor to **Port 1** of your EV3 Brick.
+
+## Modify Your Program
+
+**Code it:** Add code to the program for the Touch Sensor.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    sensors.touch1.pauseUntil(ButtonEvent.Pressed)
+    motors.largeD.run(50, 1, MoveUnit.Rotations)
+})
+```
+
+* Add a ``||sensors:pause until touch 1 pressed||`` Sensor block on top of the ``||motors:run large motor D||`` block.
+
+```block
+sensors.touch1.pauseUntil(ButtonEvent.Pressed)
+```
+
+**Download:** Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Press the Touch Sensor
+
+Confirm that the Large Motor has turned one rotation AFTER you press the Touch Sensor.
+
+![Hand Touch Sensor Pressed & EV3 Brick & Large Motor](/static/getting-started/11_TouchMotorWorking.png)
+
+Download and run the program as many times as you want in order to verify this, or tinker with different Touch Sensor and Large Motor values.
+
+## Connect a Color Sensor
+
+Now we will try to control the Large Motor using another sensor.
+
+![Hand connecting Color Sensor to Port 4, Large Motor D, EV3 Brick](/static/getting-started/12_ConnectColor.png)
+
+Keeping the Large Motor connected to **Port D**, connect the Color Sensor to **Port 4**.
+
+**Code it:** Modify Your Program to use the Color Sensor.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Green)
+    motors.largeD.run(50, 1, MoveUnit.Rotations)
+})
+```
+
+* Using the same program, replace the ``||sensors:pause until touch 1||`` block with a ``||sensors:pause color sensor 3||`` for color block.
+
+```block
+sensors.color3.pauseUntilColorDetected(ColorSensorColor.Green)
+```
+
+* Select the color you want to detect (e.g., green).
+
+**Download:** Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Place a Colored Brick in Front of the Color Sensor
+
+![IMG: Colored bricks in front of Color Sensor, hands, EV3 Brick](/static/getting-started/14_ColorSensorWorking.png)
+
+Confirm that the Large Motor has turned one rotation AFTER the Color Sensor has detected the colored brick.
+
+Download and run the program as many times as you want in order to verify this, or tinker with different Color Sensor and Large Motor values.
+
+Click on the **JavaScript** tab and change the color the Color Sensor detects to Black, Blue, Green, Yellow, Red, White, or Brown. Use Title Case for the color names.
+
+## Well Done!
+
+You have now learned how to control some of the inputs and outputs of the EV3.

docs/getting-started/use.md

@@ -0,0 +1,109 @@
+# Use
+
+Build a robot and drive into the world of robotics!
+
+![EV3 Driving Base full w/cuboid](/static/getting-started/EV3_GettingStarted_13.jpg)
+
+In this project we will guide you through building a Driving Base Robot and programming it to move straight and turn. You will also build and Object Detector Module, and program it to detect an object. It’s a good idea to have done the [Try](/getting-started/try) sequence first.
+
+## Connect
+
+What if your school had a multipurpose robot? How would you use it?
+
+![Apple Picker Robot](/static/getting-started/02_ApplePickerRobot.jpg)
+
+Would you use it to clean the school or plant trees?
+
+## Build Your Driving Base Robot
+
+Build the robot driving base:
+
+[![EV3 Driving Base](/static/lessons/common/ev3-driving-base.jpg)](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/building-instructions/ev3-rem-driving-base-79bebfc16bd491186ea9c9069842155e.pdf)
+
+## Make It Move
+
+**Code it:** Create a program that makes the Driving Base move forward and stop at the finish line, which is ``1`` meter away.
+
+Start by building this program:
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeBC.steer(0, 50, 1, MoveUnit.Rotations)
+})
+```
+
+* Drag a ``||motors:steer large motors B+C||`` block inside an ``||brick:on button||`` block.
+* Click on the **(+)** sign.
+* Change to ``1`` rotation.
+
+### ~hint
+
+**Hint:** You will have to modify the number of rotations until you find the number that matches the robot moving forward 1 meter and stopping.
+
+### ~
+
+**Download:** Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Make It Turn
+
+**Code it:** Create a new program that turns the Driving Base 180 degrees.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeBC.steer(-50, 50, 1, MoveUnit.Rotations)
+})
+```
+
+### ~hint
+
+**Hint:** You will have to modify the turn ratio and the number of rotations until the robot reaches 180 degrees.
+
+### ~
+
+**Download:** Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+## Add an Ultrasonic Sensor to Your Driving Base
+
+Build and attach an Ultrasonic Sensor to your driving base:
+
+[![EV3 Ultrasonic Sensor Driving Base Building Instructions Main Image](/static/lessons/common/ev3-ultrasonic-sensor-driving-base.jpg)](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/building-instructions/ev3-ultrasonic-sensor-driving-base-61ffdfa461aee2470b8ddbeab16e2070.pdf)
+
+## Detect an Object
+
+**Code it:**  Create a program that moves the Driving Base and makes it stop ``6`` cm from the Cuboid.
+
+Create a new program:
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    motors.largeBC.tank(50, 50)
+    sensors.ultrasonic4.setThreshold(UltrasonicSensorEvent.ObjectDetected, 6)
+    sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectDetected);
+    motors.stopAll()
+})
+```
+
+* Drag a ``||motors:tank large motors B+C||`` motor block inside the ``||brick:on button||`` block.
+* Drag the Ultrasonic Sensor threshold ``||sensors:set ultrasonic 4||``  block and place it below the motor block.
+* Drag a ``|sensors:pause until ultrasonic 4||`` block and place it under the threshold block.
+* Drag a ``||motors:stop all motors||`` block and place it below the sensor block.
+
+### ~hint
+
+**Hint:** You will have to modify the values of the Ultrasonic Sensor block until the robot reaches the desired position.
+
+### ~
+
+**Download:** Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the center button on the EV3 Brick to run the program.
+
+Click on the **JavaScript** tab. Change and test the number value of the Ultrasonic
+Sensor.
+
+```typescript
+sensors.ultrasonic4.setThreshold(UltrasonicSensorEvent.ObjectDetected, 10)
+```
+
+**Congratulations!**
+
+You are ready to move on to the next steps.
+Try a [Design Engineering](/design-engineering), [Coding](/coding), or [Maker](/maker) activity.

docs/index-ref.json

@@ -1,3 +1,3 @@
 {
-    "appref": "v"
+    "appref": "v0.1.11"
 }

docs/labview.md

@@ -0,0 +1,248 @@
+# Coding in MakeCode
+
+This guide helps users who are used to work with @boardname@ to get familiar with using blocks in MakeCode.
+
+## Snap together the blocks
+
+Just like with LabView, blocks in the MakeCode editor can be dragged from the cabinet and snapped together
+to create a sequence of program instructions.
+
+Take a look a the LabView program below: it **starts**, turns on motor A, waits a second, and finally stops motor A.
+
+![sequence of block](/static/labview/sequencing.png)     
+
+The blocks in MakeCode have similar functions and go together in the same way: they snap into the ``||loops:on start||`` block and then connect to each other vertically.
+
+```blocks
+motors.largeA.run(50)
+pause(1000)
+motors.largeA.stop()
+```
+
+Any block program can be converted to JavaScript and you can edit it as lines of code too.
+
+```typescript
+motors.largeA.run(50)
+pause(1000)
+motors.largeA.stop()
+```
+
+## Download to the EV3
+
+Before you actually run your program on the @boardname@, you can first try it in the simulator. The MakeCode editor includes a simulator in the browser for you to test your code. You can make changes to your program and check them out it the simulator to make sure your code works the way want. The similator knows when you modify your code and it restarts automatically to run the new code.
+
+Once you're ready to transfer your program to the @boardname@, click the ``|Download|`` button and follow the instructions.
+
+## Single motors
+
+This program controls a large motor on port A in several different ways. It sets just the speed and then sets speed for: an amount of time, angle of movement, and a number of rotations.
+
+![Single motor blocks](/static/labview/motors.png)       
+
+```blocks
+motors.largeA.run(50);
+motors.largeA.run(50, 1000, MoveUnit.MilliSeconds);
+motors.largeA.run(50, 360, MoveUnit.Degrees);
+motors.largeA.run(50, 1, MoveUnit.Rotations);
+motors.largeA.stop();
+```
+
+## Steering
+
+The **steering** blocks let you to synchronize two motors at a precise rate. They can also specify the duration, angle, or number of rotations for the motors to turn.
+
+![Steering blocks](/static/labview/steer.png)
+
+```blocks
+motors.largeBC.steer(0, 50);
+motors.largeBC.steer(0, 50, 1000, MoveUnit.MilliSeconds);
+motors.largeBC.steer(0, 50, 360, MoveUnit.Degrees);
+motors.largeBC.steer(0, 50, 1, MoveUnit.Rotations);
+motors.largeBC.stop();
+```
+
+## Tank
+
+The **tank** blocks control the speed of two motors. These are commonly used for a differential drive robot. The blocks can also specify the duration, angle, or number of rotations.
+
+![Tank block](/static/labview/tank.png)
+
+```blocks
+motors.largeBC.tank(50, 50);
+motors.largeBC.tank(50, 50, 1000, MoveUnit.MilliSeconds);
+motors.largeBC.tank(50, 50, 360, MoveUnit.Degrees);
+motors.largeBC.tank(50, 50, 1, MoveUnit.Rotations);
+motors.largeBC.stop();
+```
+
+## Coasting and braking
+
+By default, all motors coast when any command used to move finishes. You can keep them from coasting with the ``||motors:set brake||`` block. 
+
+![Brake block](/static/labview/brake.png)
+
+```blocks
+motors.largeD.setBrake(true);
+motors.largeD.run(50, 1, MoveUnit.Rotations)
+```
+
+## Inverting and regulating motors
+
+If you wan to change the direction that a motor turns, use the ``||motors:set inverted||`` block.
+
+![Brake block](/static/labview/invertmotor.png)
+
+```blocks
+motors.largeA.setInverted(true);
+```
+
+By default, the speed of motors is regulated. This means that if your robot goes up a hill,
+the regulator will adjust the power to match the desired speed. You can disable this feature
+using ``||motors:set regulated||``.
+
+![Brake block](/static/labview/unregulatedmotor.png)
+
+```blocks
+motors.largeA.setRegulated(false);
+```
+
+## Brick
+
+The **Brick** category has a number of blocks to display graphics on the brick screen.
+
+![brick image](/static/labview/brickimage.png)
+
+```blocks
+brick.clearScreen()
+brick.showImage(images.expressionsWink)
+```
+
+![brick status light](/static/labview/brickstatuslight.png)
+
+```blocks
+brick.setStatusLight(StatusLight.Off);
+brick.setStatusLight(StatusLight.Red);
+brick.setStatusLight(StatusLight.OrangePulse);
+```
+
+## Waiting (pausing)
+
+It is quite common to have to wait for a task to finish or for a sensor state to change, such as a touch button pressed. The ``||loops:pause||`` and ``||sensors:pause until||`` blocks provide a way for your program to wait for a period of time.
+
+![pause for time](/static/labview/pausefortime.png)      
+
+```blocks
+motors.largeD.run(50)
+pause(1000)
+motors.largeD.stop();
+```
+
+![pause for touch](/static/labview/pausefortouch.png)
+
+```blocks
+motors.largeD.run(50)
+sensors.touch1.pauseUntil(ButtonEvent.Pressed)
+motors.largeD.stop();
+```
+
+![pause for distance](/static/labview/pausefordistance.png)
+
+```blocks
+motors.largeD.run(50)
+sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectNear)
+motors.largeD.stop();
+```
+
+You can also use the ``||loops:pause until||`` block to wait on any [boolean](/types/boolean) expression. As your program runs, it waits until the condition (expression) inside becomes true.
+
+```blocks
+motors.largeD.run(50)
+pauseUntil(() => sensors.touch1.isPressed())
+motors.largeD.stop()
+```
+
+## Loops
+
+![Single loop](/static/labview/loopinfinite.png)
+
+```blocks
+forever(() => {
+    motors.largeD.run(50, 1, MoveUnit.Rotations);
+    motors.largeD.run(-50, 1, MoveUnit.Rotations);
+})
+```
+
+![While loop](/static/labview/while.png)
+
+```blocks
+for(let i = 0; i < 10; i++) {
+    motors.largeD.run(50, 1, MoveUnit.Rotations);
+    motors.largeD.run(-50, 1, MoveUnit.Rotations);
+}
+let k = 0;
+while(k < 10) {
+    motors.largeD.run(50, 1, MoveUnit.Rotations);
+    motors.largeD.run(-50, 1, MoveUnit.Rotations);    
+    k++;
+}
+```
+
+## Variables
+
+![Variable block](/static/labview/speedoflightvar.png)
+
+```blocks
+let light = 0;
+forever(function () {
+    light = sensors.color3.light(LightIntensityMode.Reflected);
+    motors.largeD.run(light)
+})
+```
+
+## Concurrent loops
+
+You can start up multiple ``||loops:forever||`` loops that will run at the same time. Actually, only the code in just one of the loops is really running at any exact moment in time. Each loop, though, gets a turn to run all of its code and this makes them run [_concurrently_](https://en.wikipedia.org/wiki/Concurrent_computing).
+
+![Multiple loops running at the same time](/static/labview/multipleloops.png)
+
+```blocks
+forever(() => {
+    motors.largeD.run(50, 1, MoveUnit.Rotations);
+    motors.largeD.run(-50, 1, MoveUnit.Rotations);
+})
+forever(() => {
+    brick.showImage(images.eyesMiddleRight)
+    pause(1000)
+    brick.showImage(images.eyesMiddleLeft)
+    pause(1000)
+})
+```
+
+## Conditional
+
+The ``||logic:if||`` block allows you to run different code depending on whether some condition ([boolean](/types/boolean) expression) is `true` or `false`. Also, this is similar to the ``||loops:switch||`` block.
+
+![Brake block](/static/labview/ife.png)
+
+```blocks
+forever(function() {
+    if(sensors.touch1.isPressed()) {
+        motors.largeD.run(50)
+    } else {
+        motors.largeD.stop()
+    }
+})
+```
+
+## Random
+
+The ``||math:pick random||`` block returns a random number selected from a range of numbers.
+
+![Brake block](/static/labview/random.png)
+
+```blocks
+forever(function () {
+    motors.largeBC.steer(Math.randomRange(-5, 5), 50)
+    pause(100)
+})
+```

docs/lessons.md

@@ -0,0 +1,27 @@
+# Lessons
+
+Learning activities for @boardname@ with MakeCode.
+
+## Motors and motion
+
+```codecard
+[{
+    "name": "Make it Move",
+    "imageUrl":"/static/lessons/make-it-move.jpg",
+    "url": "/lessons/make-it-move",
+    "cardType": "project",
+    "description": "Make a robot that moves itself without wheels."
+}, {
+    "name": "Make it Move TUTORIAL",
+    "imageUrl":"/static/lessons/make-it-move.jpg",
+    "url": "/lessons/make-it-move-tutorial",
+    "cardType": "tutorial",
+    "description": "Make a robot that moves itself without wheels."
+}, {
+    "name": "Line Detection",
+    "imageUrl":"/static/lessons/line-detection.jpg",
+    "url": "/lessons/line-detection",
+    "cardType": "project",
+    "description": "Make your robot drive itself by following lines."
+}]
+```

docs/lessons/classroom-management.md

@@ -0,0 +1,68 @@
+# Classroom Management Tips
+
+## Lesson Planning
+
+### Required Materials
+
+* [@boardname@ Core Set](https://education.lego.com/enus/products/legomindstormseducationev3coreset/5003400)
+* Lesson plan
+* Student Worksheet for each activity
+* Inspirational images for each activity
+* Modeling materials already available in your classroom
+
+### How much time do you need?
+
+Each lesson is designed to take 90 minutes. If you work in shorter class periods, you can break this down into two 45 minute sessions.
+
+### Preparation
+
+It is important to establish student groups. Groups of two work well. Ensure that each student has a copy of the Student Worksheet for recording their design process, or alternatively, they can use their own preferred method for recording their design journey. They will also need the @boardname@ Core Set (one set for every two students is recommended).
+
+### Prior Learning
+
+Before beginning these Maker activities, it is recommended that students complete the lessons from the Introduction to Robotics Lesson Plan. These lessons can be found in both EV3 Lab and EV3 Programming. These tutorial lessons last between 45 - 90 minutes each, and you will need to factor this into your lesson planning.
+
+However, if you prefer a more open-ended, explorative method, you can start out with this activity and allow students to find help on their own by referring to the Robot Educator Tutorials.
+
+## The LEGO Education Maker (Design) Process #design-process
+
+### Defining the Problem
+
+It is important that students define a real problem to solve, or find a new design opportunity from the start. The “Connect” images are provided to help students think about designing their solutions. At this stage of the process, it is important that you not show examples of a final or sample solution.
+
+### Brainstorm
+
+Brainstorming is an active part of making. Some students will find it easier to explore their thoughts through tinkering (hands-on experimentation) with the LEGO bricks, and others will prefer to record sketches and notes. Group work is essential, but it is important to allow time for students to work alone before sharing their ideas with their groups.
+
+### Define the Design Criteria
+
+Discussing and reaching an agreement about the best solution to build can involve a lot of negotiation and may require different techniques that are dependent on the students’ skills. For example:
+
+* Some students draw well.
+* Others may build part of a model, and then describe what they mean.
+* Other students may be good at describing a strategy.
+
+Encourage an ethos where students can share anything, no matter how abstract it might sound. Be active during this phase and ensure that the ideas the students choose are achievable.
+
+It is important that students set clear design criteria. Once the solution to the problem has been made, the students will return to these criteria, which will then form the basis for testing how well their solution works.
+
+### Go Make
+
+Students must make one of their ideas using the LEGO set, and can use other materials if needed. If they are finding it hard to build their idea, encourage them to break problems down into smaller parts. Explain that they do not have to come up with the whole solution from the start. Remind students that this process is iterative and they must test, analyze, and revise their idea as they go.
+
+Using this Maker process does not mean you are following an inflexible set of steps. Instead, think of it as a set of practices.
+For example, brainstorming may be prominent at the beginning of the process. However, students may also need to brainstorm ideas when they are trying to figure out ways to improve their idea, or when they have a bad test result and must change a feature of their design.
+
+### Review and Revise Your Solution
+
+To help students develop their critical thinking and communication skills, you may wish to have students from one group observe and critique another group’s solution. Peer review and formative feedback helps both the students giving, and the students receiving the feedback to improve their work.
+
+### Communicate Your Solution
+
+The Student Worksheet is helpful for basic documentation of the activity. Students can also refer to it when presenting their work in front of the class. You may also wish to use the Student Worksheet as a portfolio for performance evaluations or for student self-evaluation.
+
+## Maker (Design) Process Diagram
+
+Here's a diagram to quickly illustrate the steps of the Maker (Design) Process. You can copy and print this as a poster to give to the students.
+
+![Design process diagram](/static/lessons/common/lego-maker-design-process-large.jpg)

docs/lessons/line-detection.md

@@ -0,0 +1,268 @@
+# Line Detection
+
+## Objective
+
+Design ways to improve driving safety by helping to prevent drivers from falling asleep and causing an accident.
+ 
+![Car driving on highway](/static/lessons/line-detection/car-driving.jpg)
+
+## Connect
+
+Make sure that you can answer the following questions:
+
+* Can autonomous cars react to different traffic light signals?
+* What can happen if a driver falls asleep while driving?
+* How can we detect when a driver is falling asleep?
+
+Think about what you have learned, then document it. Describe the problem in your own words. Creatively record your ideas and findings.
+
+## Construct
+
+Start by constructing this model. Read the building instructions [here](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/building-instructions/ev3-rem-color-sensor-down-driving-base-d30ed30610c3d6647d56e17bc64cf6e2.pdf) first.
+
+![Color sensor on the driving base](/static/lessons/line-detection/color-sensor-driving.jpg)
+
+## Program
+
+Autonomous cars need to recognize and respond to traffic lights automatically.
+First, create a program that will make your robot stop at red lights.
+Make sure your robot is only responding to the color red.
+Once you have succeeded, program your robot to drive forward again when the light changes from red to green.
+
+There are two coding tasks for this lesson:
+
+1. Create a program that will make your robot stop at red lights.
+2. Create a program that drives the robot forward until the Color Sensor sees red. The robot then stops.
+
+## Coding task 1 - Stop at red lights
+
+**Goal:** Create a program that will make your robot stop at red lights.
+
+### Step 1
+
+Create a program that drives the robot forward until the Color Sensor sees red. The robot then stops.
+
+Place a ``||motors:steer large B+C||`` block from ``||motors:Motors||`` under ``||loops:on start||``. Change the speed to 20%.
+
+```blocks 
+motors.largeBC.steer(0, 20)
+```
+
+### Step 2
+
+Place a ``||loops:while||`` loop block under ``||motors:steer large B+C||``.  
+
+```blocks
+motors.largeBC.steer(0, 20)
+while (true) {
+}
+```
+
+### Step 3
+
+Place a ``||sensors:pause until color detected||`` from ``||sensors:Sensors||`` inside the ``||loops:while||`` loop block. Change the color to red.
+ 
+```blocks
+motors.largeBC.steer(0, 20)
+while (true) {
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+}
+```
+
+### Step 4
+
+Place a ``||motors:stop all motors||`` block under the ``||sensors:pause until color detected||`` block.
+
+Study the program...what do you think the program will do?
+
+**Hint:** The motors will run until the Color Sensor senses the color red, then all motors will stop. The motors will run until the sensor reading in the while block is true.
+
+```blocks
+motors.largeBC.steer(0, 20)
+while (true) {
+    sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+    motors.stopAll()
+}
+```
+
+### Step 5
+
+Click `|Download|` and follow the instructions to get your code onto your EV3 Brick. Press the **center** button on the EV3 Brick to run the program.
+
+## Coding task 2 - Detect light changes
+
+**Goal:** Program your robot to drive forward again when the light changes from red to green.
+
+### Step 1
+
+Place a ``||loops:while||`` loop block under ``||loops:on start||``.
+
+```blocks
+while (true) {
+    
+}
+```
+
+### Step 2
+
+Place a ``||motors:steer large B+C||`` block from ``||motors:Motors||`` inside the ``||loops:while||`` loop block. Change the speed to 20%.
+
+```blocks
+while (true) {
+    motors.largeBC.steer(0, 20)
+}
+```
+ 
+### Step 4
+
+Place a ``||loops:while||`` loop block under the ``||motors:steer large B+C||``  block.
+
+```blocks
+while (true) {
+    motors.largeBC.steer(0, 20)
+    while (true) {
+        
+    }
+}
+```
+
+### Step 5
+
+Place a ``||sensors:pause until color detected||`` block from ``||sensors:Sensors||`` inside the ``||loops:while||`` loop block. Change the color to red.
+
+```blocks
+while (true) {
+    motors.largeBC.steer(0, 20)
+    while (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+    }
+}
+```
+
+### Step 6
+
+Place a ``||motors:stop all motors||`` block under the ``||sensors:pause until color detected||`` block.  
+
+```blocks
+while (true) {
+    motors.largeBC.steer(0, 20)
+    while (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+        motors.stopAll()
+    }
+}
+```
+
+### Step 7
+
+Place a ``||loops:while||`` loop block under the second ``||loops:while||`` loop block.
+
+```blocks
+while (true) {
+    motors.largeBC.steer(0, 20)
+    while (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+        motors.stopAll()
+    }
+    while (true) {
+        
+    }
+}
+```
+
+### Step 8
+
+Place a ``||sensors:pause unril color detected||`` block inside the new ``||loops:while||`` loop block. Change the color to red.
+
+What do you think the program will do?
+
+**Hint:** The motors will run until the Color Sensor detects the color red, then it will stop all motors. The motors will also run and not stop when the color sensor detects the color green.
+ 
+```blocks
+while (true) {
+    motors.largeBC.steer(0, 20)
+    while (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+        motors.stopAll()
+    }
+    while (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+    }
+}
+```
+
+### Step 9
+
+Click `|Download|` and follow the instructions to get your code onto your EV3 Brick. Press the **center** button on the EV3 Brick to run the program.
+ 
+## Contemplate
+
+To simulate what could happen if a driver falls asleep while driving, your robot could sound an alarm signal when it crosses the line. This feature is often available in new cars.
+
+Program your robot to perform this function.
+
+Think about what you have learned, then document it. Describe your pseudocode for this task. Creatively record your ideas, and findings.
+
+### Programming hint
+
+```blocks
+motors.largeBC.steer(0, 20)
+while (true) {
+sensors.color3.pauseUntilColorDetected(ColorSensorColor.Yellow)
+music.playSoundEffect(sounds.systemGeneralAlert)
+}
+while (true) {
+    while (true) {      
+        sensors.color3.pauseUntilLightDetected(LightIntensityMode.Reflected, Light.Bright)
+        motors.largeB.run(10)
+        motors.largeC.run(-10)
+    }
+    while (true) {
+        sensors.color3.pauseUntilLightDetected(LightIntensityMode.Reflected, Light.Bright)
+        motors.largeA.run(-10)
+        motors.largeA.run(10)
+    }
+}
+```
+
+## Continue
+
+Program your robot to drive on “autopilot” along a given route. You will need to create a program that recognizes and responds to a dark line (or white line). You will create a line-following program and your robot will need to travel along the line without losing contact with it.
+
+You will need to constantly debug your program in order to make your robot travel as smoothly as possible along the line.
+
+### Programming hint
+
+```blocks
+while (true) {
+    while (true) {   
+        sensors.color3.pauseUntilLightDetected(LightIntensityMode.Reflected, Light.Bright)
+        motors.largeB.run(10)
+        motors.largeC.run(-10)
+    }
+    while (true) {
+        sensors.color3.pauseUntilLightDetected(LightIntensityMode.Reflected, Light.Bright)
+        motors.largeB.run(-10)
+        motors.largeC.run(10)
+    }
+}
+```
+
+## Share
+
+Consider the following questions:
+
+1. What challenged you? 
+2. Where there any surprises? 
+3. How could you improve your program?
+4. Could your program have been more streamlined? 
+5. Have you used too many blocks?
+6. Is there a more efficient way of building your program?
+7. How could your program be used in real-world scenarios?
+
+Think about what you have learned, then document it. Creatively record and present your ideas, creations, and findings.
+
+
+
+
+

docs/lessons/make-it-move-tutorial.md

@@ -0,0 +1,72 @@
+# Make It Move Without Wheels 
+
+## Objective @unplugged
+
+Design, build and program a robot that can move itself:
+
+Your robot will:
+
+* Go a distance of at least 30cm
+* Use at least one motor
+* Use NO wheels for locomotion
+
+![@boardname@ with parts](/static/lessons/make-it-move/locomotion-no-wheels.jpg)
+
+
+## Construct @unplugged
+
+Build a Walker Bot!
+
+The Walker Bot is one example of many possible solutions for making a robot move without wheels.
+
+The Walker Bot combines an EV3 Frame and two legs that are mirror-images to create left and right legs.
+
+The legs in the Walker Bot are designed to show how to change the rotary motion of a motor to reciprocating motion.
+
+Start by reading [these](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/ev3-dep/building%20instructions/walker-bot-bi-180fc24f9298e1dd6201099627d43903.pdf) instructions first.
+ 
+![@boardname@ Walker Bot](/static/lessons/make-it-move/walker-bot.jpg)
+
+ 
+## Program 1 @fullscreen
+
+In nature, creatures use many methods to get around. None of them, however, use wheels to move. Can we copy the method of animal locomotion with our robot? Using motors and legs, make the robot move without using any wheels.
+
+Place a ``||motors:tank large B+C||`` block from ``||motors:Motors||`` under ``||loops:on start||``.
+
+Change the speed to `-60%` (for motor B) and `+60%` (for motor C).
+Change the rotations to `9`.
+
+The ``||motors:tank large B+C||`` block will run for `9` rotations when the **center** button is pressed on the EV3 brick. The motors are set for the reverse direction because they are mounted upside down in this model.
+
+```blocks
+motors.largeBC.tank(-60, 60, 9, MoveUnit.Rotations)
+```
+
+## Program 2 @fullscreen
+
+Place a ``||motors:stop all motors||`` block under ``||motors:tank large B+C||``.
+
+The ``||motors:tank large B+C||`` block will run for `9` rotations when the **center** button is pressed on the EV3 brick then stop.
+
+```blocks
+motors.largeBC.tank(-60, 60, 9, MoveUnit.Rotations)
+motors.stopAll()
+```
+
+## Program 3 @fullscreen
+
+Place a ``||brick:show string||`` block under ``||motors:stop all motors||``.
+Change the `"Hello World"` text to `"30 cm"`.
+
+The ``||motors:tank large B+C||`` will run for `9` rotations when the **center** button is pressed on the EV3 brick then stop and display "30 cm" on the EV3 Brick’s screen.
+
+```blocks
+motors.largeBC.tank(-60, 60, 9, MoveUnit.Rotations)
+motors.stopAll()
+brick.showString("30 cm", 1)
+```
+
+## Download @fullscreen
+
+Click `|Download|` and follow the instructions to get your code onto your EV3 Brick. Press the **center** button on the EV3 Brick to run the program.

docs/lessons/make-it-move.md

@@ -0,0 +1,73 @@
+# Make It Move Without Wheels 
+
+## Objective
+
+Design, build and program a robot that can move itself:
+
+Your robot will:
+
+* Go a distance of at least 30cm
+* Use at least one motor
+* Use NO wheels for locomotion
+
+![@boardname@ with parts](/static/lessons/make-it-move/locomotion-no-wheels.jpg)
+
+## Construct
+
+Build a Walker Bot!
+
+The Walker Bot is one example of many possible solutions for making a robot move without wheels.
+
+The Walker Bot combines an EV3 Frame and two legs that are mirror-images to create left and right legs.
+
+The legs in the Walker Bot are designed to show how to change the rotary motion of a motor to reciprocating motion.
+
+Start by reading [these](https://le-www-live-s.legocdn.com/sc/media/lessons/mindstorms-ev3/ev3-dep/building%20instructions/walker-bot-bi-180fc24f9298e1dd6201099627d43903.pdf) instructions first.
+ 
+![@boardname@ Walker Bot](/static/lessons/make-it-move/walker-bot.jpg)
+
+ 
+## Program
+
+In nature, creatures use many methods to get around. None of them, however, use wheels to move. Can we copy the method of animal locomotion with our robot? Using motors and legs, make the robot move without using any wheels.
+
+### Step 1
+
+Place a ``||motors:tank large B+C||`` block from ``||motors:Motors||`` under ``||loops:on start||``.
+
+Change the speed to `-60%` (for motor B) and `+60%` (for motor C).
+Change the rotations to `9`.
+
+The ``||motors:tank large B+C||`` block will run for `9` rotations when the **center** button is pressed on the EV3 brick. The motors are set for the reverse direction because they are mounted upside down in this model.
+
+```blocks
+motors.largeBC.tank(-60, 60, 9, MoveUnit.Rotations)
+```
+
+### Step 2
+
+Place a ``||motors:stop all motors||`` block under ``||motors:tank large B+C||``.
+
+The ``||motors:tank large B+C||`` block will run for `9` rotations when the **center** button is pressed on the EV3 brick then stop.
+
+```blocks
+motors.largeBC.tank(-60, 60, 9, MoveUnit.Rotations)
+motors.largeBC.stop()
+```
+
+### Step 3
+
+Place a ``||brick:show string||`` block under ``||motors:stop all motors||``.
+Change the `"Hello World"` text to `"30 cm"`.
+
+The ``||motors:tank large B+C||`` will run for `9` rotations when the **center** button is pressed on the EV3 brick then stop and display "30 cm" on the EV3 Brick’s screen.
+
+```blocks
+motors.largeBC.tank(-60, 60, 9, MoveUnit.Rotations)
+motors.largeBC.stop()
+brick.showString("30 cm", 1)
+```
+
+### Step 4
+
+Click `|Download|` and follow the instructions to get your code onto your EV3 Brick. Press the **center** button on the EV3 Brick to run the program.

docs/maker.md

@@ -1,47 +1,28 @@
 # Maker Activites
 
-These six activities require the LEGO® MINDSTORMS® Education EV3 Core Set (45544). Supporting materials for teachers and middle school students are provided, offering everything teachers and students need to explore their inner makers as they follow the design process to solve open-ended, themed challenges...
+These six activities require the [@boardname@ Core Set (45544)](https://education.lego.com/en-us/products/lego-mindstorms-education-ev3-core-set-/5003400). Supporting materials for teachers and middle school students are provided, offering everything teachers and students need to explore their inner makers as they follow the design process to solve open-ended, themed challenges...
 
-* [Download Curriculum Materials](https://education.lego.com/en-us/downloads/mindstorms-ev3)
+* [Download Curriculum Materials](https://education.lego.com/en-us/downloads/mindstorms-ev3/curriculum)
 
 ## Activites
 
 ```codecard
 [
 {
-  "name": "Sound Machine",
-  "description": "Create instruments with your EV3 Brick!",
+  "name": "Make A Sound Machine",
+  "description": "Make a Sound Machine that can play a rhythm, music or just noise!",
   "url":"/maker/sound-machine",
   "cardType": "example",
-  "imageUrl": "/static/maker/sound-machine.png"
+  "imageUrl": "/static/lessons/make-a-sound-machine.png",
+  "cardType": "side"  
 },
 {
-  "name": "Sound Of Color",
-  "description": "Play different sounds based on the color",
-  "url":"/maker/sound-of-color",
-  "cardType": "example",
-  "imageUrl": "/static/maker/sound-of-color.png"
-},
-{
-  "name": "Security Gadget",
-  "description": "Raise the alarm when your brick is lifted!",
+  "name": "Make A Security Gadget",
+  "description": "Invent a Security Gadget that will protect your belongings by warning you!",
   "url":"/maker/security-gadget",
   "cardType": "example",
-  "imageUrl": "/static/maker/security-gadget.png"
-},
-{
-  "name": "Intruder Detector",
-  "description": "Raise the alarm when an intruder sneaks in",
-  "url":"/maker/intruder-detector",
-  "cardType": "example",
-  "imageUrl": "/static/maker/intruder-detector.png"
-},
-{
-  "name": "Puppet",
-  "description": "Build an automated puppet",
-  "url":"/maker/puppet",
-  "cardType": "example",
-  "imageUrl": "/static/maker/puppet.png"
+  "imageUrl": "/static/lessons/make-a-security-device.png",
+  "cardType": "side"  
 }
 ]
 ```

docs/maker/intruder-detector.md

@@ -1,11 +0,0 @@
-# Intruder Detector
-
-This program will activate an alarm when an object moves in front of the Ultrasonic Sensor.
-
-TODO support for event when value changes
-
-```blocks
-input.ultrasonic4.onObjectNear(function () {
-    music.playSoundUntilDone(music.sounds(Sounds.PowerUp))
-})
-```

docs/maker/movement-detector.md

@@ -0,0 +1,9 @@
+# Movement Detector
+
+This program will activate an alarm when an object moves in front of the Ultrasonic Sensor.
+
+```blocks
+sensors.ultrasonic4.onEvent(UltrasonicSensorEvent.ObjectNear, function () {
+    music.playSoundEffectUntilDone(sounds.informationActivate)
+})
+```

docs/maker/puppet.md

@@ -3,15 +3,13 @@
 Use this program with the Programmable Brick and Large Motor.
 
 ```blocks
-loops.forever(function () {
-    output.largeMotorA.setPower(30)
-    output.largeMotorA.on(true)
-    loops.pause(100)
-    output.largeMotorA.on(false)
-    music.playSoundUntilDone(music.sounds(Sounds.PowerUp))
-    output.largeMotorA.setPower(-30)
-    output.largeMotorA.on(true)
-    loops.pause(100)
-    output.largeMotorA.on(false)
+forever(function () {
+    motors.largeA.run(30)
+    pause(100)
+    motors.largeA.stop()
+    music.playSoundEffectUntilDone(sounds.animalsCatPurr)
+    motors.largeA.run(-30)
+    pause(100)
+    motors.largeA.stop()
 })
 ```

docs/maker/security-gadget.md

@@ -1,9 +1,139 @@
-# Security Gadget
 
-This program will activate an alarm when an object is lifted from the Touch Sensor.
+# Make a Security Gadget
+
+Invent a Security Gadget that will protect your belongings by warning you!
+
+![Maker – Make a Security Gadget Main Image](/static/lessons/make-a-security-gadget/lego-maker-security-detect.jpg)
+
+## Connect 
+
+Over time, people have come up with many different ways to help protect their personal belongings from theft. These inventions include simple alarm systems and even traps! 
+
+![Make a Security Gadget 3 Stock Footage Images](/static/lessons/make-a-security-gadget/three-stock.jpg)
+
+Look at the photos and think about:
+
+* What do you see?
+* Can you see any new design opportunities?
+* What problems can you see?
+* How could you make use of the LEGO bricks, the EV3 Programmable Brick, motors, and sensors?
+
+### Things You’ll Need
+
+* [@boardname@ Core Set](https://education.lego.com/enus/products/legomindstormseducationev3coreset/5003400)
+
+Additional materials to add to your Security Gadget:
+
+* String
+* Arts and crafts materials such as:
+>* Cardboard
+>* Construction paper
+>* Pipe cleaners
+>* Plastic or paper cups 
+>* Recycled materials
+>* Rubber bands
+>* Wire
+
+### Prior Knowledge
+
+This activity uses sensor inputs. You may want to try the [Use](/getting-started/use) or [Object Detection](/coding/object-detection) activity before this one. Or, you can start out with this activity and tinker with coding sensor inputs on your own.
+
+## Contemplate
+
+Follow the steps of the [Maker Design Process](/lessons/classroom-management#design-process) for this lesson:
+
+![LEGO Education Maker Design Process](/static/lessons/common/lego-maker-design-process.jpg)
+
+### Defining the Problem
+
+1. What problems did you imagine? 
+2. Pick one problem and explain it to a partner.
+
+### Brainstorm
+
+Now that you have defined a problem, start to generate ideas for solving it. 
+
+### ~hint
+
+Some things to do while brainstorming:
+
+* Use the bricks from the LEGO set to help you brainstorm or sketch your ideas on paper.
+* The goal of brainstorming is to explore as many solutions as possible. You can use the tinkering examples in the Sample Solutions section below as inspiration for getting started.
+* Share your ideas and get some feedback. It may lead to more ideas!
+
+### ~ 
+
+### Define the Design Criteria
+
+1. You should have generated a number of ideas. Now select the best one to make. 
+2. Write out two or three specific design criteria your design must meet.
+
+### Go Make
+
+It is time to start making!
+
+* Use the components from the @boardname@ Core Set and additional materials to make your chosen solution. 
+* Test and analyze your design as you go and record any improvements that you make. 
+
+### Review and Revise Your Solution
+
+* Have you managed to solve the problem that you defined? 
+* Look back at your design criteria. How well does your solution work? 
+* How can you improve your design?
+
+### Communicate Your Solution
+
+Now that you have finished you can:
+
+* Make a sketch or take a photo or video of your model.
+* Label the three most important parts and explain how they work.
+* Share your work with others.
+
+## Continue
+
+### Phone Protector - Sample Solution
+
+This example program combined with the small model will sound an alarm if someone picks it up. The program activates an alarm when an object is lifted from the Touch Sensor.
+
+![Security Gadget Tinkering Example #1 – Phone Stand](/static/lessons/make-a-security-gadget/lego-maker-security-gadget.jpg)
+
+#### Programming
+
+1. Drag a ``||sensors:pause until touch||`` block and place it inside the ``||loops:forever||`` loop.
+2. Drag a ``||music:play sound effect||`` block and place it below the ``||sensors:pause until||`` block.
+3. Change the sound effect to ``mechanical horn1``.
 
 ```blocks
-input.touchSensor1.onEvent(TouchSensorEvent.Released, function () {
-    music.playSoundUntilDone(music.sounds(Sounds.PowerUp))
+forever(function () {
+    sensors.touch1.pauseUntil(ButtonEvent.Pressed)
+    music.playSoundEffect(sounds.mechanicalHorn1)
 })
-```
+```
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the ``center`` button on the EV3 Brick to run the program.
+
+### Object Detection - Sample Solution
+
+This example program combined with the small model will sound an alarm if someone (or something) crosses its path! The program activates an alarm when an object moves in front of the Ultrasonic Sensor.
+
+![Security Gadget Tinkering Example #1 – Mouse detector](/static/lessons/make-a-security-gadget/lego-maker-security-detect.jpg)
+
+#### Programming
+
+1. Drag a ``||sensors:pause until ultrasonic||`` block and place it inside the ``||loops:forever||`` loop.
+2. Drag a ``||music:play sound effect||`` block and place it below the ``||sensors:pause until||`` block.
+3. Change the sound effect to ``mechanical horn1``.
+
+```blocks
+forever(function () {
+    sensors.ultrasonic4.pauseUntil(UltrasonicSensorEvent.ObjectDetected)
+    music.playSoundEffect(sounds.mechanicalHorn1)
+})
+```
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the ``center`` button on the EV3 Brick to run the program.
+
+### Well done!
+
+Click [here](/examples) to try out some more projects!
+

docs/maker/sound-machine.md

@@ -1,12 +1,164 @@
-# Sound Machine
+# Make a Sound Machine
+
+Make a Sound Machine that can play a rhythm, music or just noise!
+
+![Maker – Make a Sound Machine Main Image](/static/lessons/make-a-sound-machine/lego-maker-sound-machine-1.jpg)
+
+## Connect 
+
+Music is made up of a combination of sounds, notes and rhythm. A rhythm is a regular movement or repeated pattern of movements that can be used in many different ways. In mechanical machines, a rhythm can help keep a machine running smoothly. It can also be used to generate different sounds in music. 
+
+![Sound Machine 3 Stock Footage Images](/static/lessons/make-a-sound-machine/three-stock.jpg)
+
+Look at the photos and think about:
+
+* What do you see?
+* Can you see any new design opportunities?
+* What problems can you see?
+* How could you make use of the LEGO bricks, the EV3 Programmable Brick, motors, and sensors?
+
+### Things You’ll Need
+
+* [@boardname@ Core Set](https://education.lego.com/enus/products/legomindstormseducationev3coreset/5003400)
+
+Additional materials to add to your Sound Machine:
+
+* Small musical instruments, such as chimes, bells, and small drums
+* Arts and crafts materials such as:
+>* Cardboard
+>* Construction paper
+>* Pipe cleaners
+>* Plastic or paper cups 
+>* Recycled materials
+>* Rubber bands
+>* Wire
+
+### Prior Knowledge
+
+This activity uses motor rotations and sensor inputs. You may want to try the [Use](/getting-started/use) or [Object Detection](/coding/object-detection) activity before this one. Or, you can start out with this activity and tinker with coding motor and sensor inputs on your own.
+
+## Contemplate
+
+Follow the steps of the [Maker Design Process](/lessons/classroom-management#design-process) for this lesson:
+
+![LEGO Education Maker Design Process](/static/lessons/common/lego-maker-design-process.jpg)
+
+### Defining the Problem
+
+1. What problems did you imagine? 
+2. Pick one problem and explain it to a partner.
+
+### Brainstorm
+
+Now that you have defined a problem, start to generate ideas for solving it. 
+
+### ~hint
+
+Some things to do while brainstorming:
+
+* Use the bricks from the LEGO set to help you brainstorm or sketch your ideas on paper.
+* The goal of brainstorming is to explore as many solutions as possible. You can use the tinkering examples in the Sample Solutions section below as inspiration for getting started.
+* Share your ideas and get some feedback. It may lead to more ideas!
+
+### ~
+
+### Define the Design Criteria
+
+* You should have generated a number of ideas. Now select the best one to make. 
+* Write out two or three specific design criteria your design must meet.
+
+### Go Make
+
+It is time to start making!
+
+* Use the components from the @boardname@ Core Set and additional materials to make your chosen solution. 
+* Test and analyze your design as you go and record any improvements that you make. 
+
+### Review and Revise Your Solution
+
+* Have you managed to solve the problem that you defined? 
+* Look back at your design criteria. How well does your solution work? 
+* How can you improve your design?
+
+### Communicate Your Solution
+
+Now that you have finished you can:
+* Make a sketch or take a photo or video of your model.
+* Label the three most important parts and explain how they work.
+* Share your work with others.
+
+## Continue
+
+### Rhythm Maker - Sample Solution
 
 This example program combined with the small model will make a beat and rhythm on any surface when the program is run.
 
+![Sound Machine Tinkering Example](/static/lessons/make-a-sound-machine/lego-maker-sound-machine.jpg)
+
+#### Programming
+
+1. Drag a run ``||motors:large motor A||`` block inside the ``||loops:forever||`` loop.
+2. Press the **(+)**.
+3. Change the rotations to `2`.
+4. Drag a ``||loops:pause||`` block and place it under the motor block.
+5. Change the duration to ``200`` ms.
+6. Drag a ``||run large motor A||`` block inside the ``||loops:forever||`` loop.
+7. Press the **(+)**.
+8. Change the power to `100`.
+9. Change the rotations to `1`.
+
 ```blocks
-loops.forever(function () {
-    output.motorA.on(50)
-    loops.pause(200)
-    output.motorA.on(100)
-    loops.pause(200)
+forever(function () {
+    motors.largeA.run(50, 2, MoveUnit.Rotations)
+    pause(200)
+    motors.largeA.run(100, 1, MoveUnit.Rotations)
 })
-``` 
+```
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the ``center`` button on the EV3 Brick to run the program.
+
+### Color Sensor Sounds - Sample Solution
+
+You can also tinker with the use of sensors.
+
+![Sound Machine Color Sensor](/static/lessons/make-a-sound-machine/lego-maker-sound-machine-color-sensor.jpg)
+
+#### Programming
+
+1. Drag an ``||logic:if else||`` Logic block and place it inside the ``||loops:forever||`` loop.
+2. Drag a ``||sensors:pause color sensor||`` block and place it inside the ``||logic:if true then||`` block.
+3. Change the color to ``blue``.
+4. Drag a ``||music:play tone||`` block and place under the sensor block.
+5. Change the tone to ``Middle G`` (392 Hz).
+6. Drag a ``||sensors:pause color sensor||`` block and place it inside the ``||logic:else||`` block.
+7. Change the color to ``red``.
+8. Drag a ``||music:play tone||`` block and place under the new sensor block.
+9. Change the tone to ``High C`` (523 Hz).
+10. Press the **(+)**.
+11. Drag a ``||sensors:pause color sensor||`` block and place it inside the ``||logic:else if||`` block.
+12. Change the color to ``green``.
+13. Drag a ``||music:play tone||`` block and place under the new sensor block.
+14. Change the tone to ``High D`` (587 Hz).
+
+```blocks
+forever(function () {
+    if (true) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Blue)
+        music.playTone(392, music.beat(BeatFraction.Whole))
+    } else if (false) {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Red)
+        music.playTone(523, music.beat(BeatFraction.Half))
+    } else {
+        sensors.color3.pauseUntilColorDetected(ColorSensorColor.Green)
+        music.playTone(587, music.beat(BeatFraction.Half))
+    }
+})
+```
+
+Click **Download** and follow the instructions to get your code onto your EV3 Brick. Press the ``center`` button on the EV3 Brick to run the program.
+
+### Well done!
+
+Click [here](/examples) to try out some more projects!
+
+

docs/maker/sound-of-color.md

@@ -3,13 +3,13 @@
 This program will play different sounds when the wheel is rotated. The sound is determined by which color is placed in front of the color Sensor.
 
 ```blocks
-input.color3.onColorDetected(ColorSensorColor.Blue, function () {
+sensors.color3.onColorDetected(ColorSensorColor.Blue, function () {
     music.playTone(Note.G4, music.beat(BeatFraction.Half))
 })
-input.color3.onColorDetected(ColorSensorColor.Red, function () {
+sensors.color3.onColorDetected(ColorSensorColor.Red, function () {
     music.playTone(Note.C5, music.beat(BeatFraction.Half))
 })
-input.color3.onColorDetected(ColorSensorColor.Green, function () {
+sensors.color3.onColorDetected(ColorSensorColor.Green, function () {
     music.playTone(Note.D5, music.beat(BeatFraction.Half))
 })
 ```

docs/reference.md

@@ -1,8 +1,24 @@
 # Reference
 
+```namespaces
+music.playSoundEffect(sounds.animalsCatPurr);
+sensors.color(null);
+motors.stopAll();
+brick.showMood(moods.sleeping);
+```
 
+## Advanced
+
+```namespaces
+console.log("");
+control.runInParallel(function(){});
+```
 
 ## See Also
 
-[touch sensor](/reference/sensors/touch-sensor),
-[color sensor](/reference/sensors/color-sensor)
+[brick](/reference/brick),
+[sensors](/reference/sensors),
+[motors](/reference/motors),
+[music](/reference/music),
+[control](/reference/control),
+[console](/reference/console)

docs/reference/brick.md

@@ -0,0 +1,31 @@
+# Brick
+
+## Screen
+
+```cards
+brick.showMood(moods.sleeping);
+brick.showImage(images.expressionsBigSmile);
+brick.showString("Hello world!", 1);
+brick.showNumber(0, 1);
+brick.showValue("item", 0, 1);
+brick.clearScreen();
+brick.showPorts();
+```
+
+## Buttons
+
+```cards
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+
+});
+brick.buttonEnter.pauseUntil(ButtonEvent.Bumped);
+brick.buttonEnter.isPressed()
+brick.setStatusLight(StatusLight.Red);
+brick.buttonEnter.wasPressed()
+```
+
+## Other
+
+```cards
+brick.batteryLevel()
+```

docs/reference/brick/battery-level.md

@@ -0,0 +1,33 @@
+# battery Level
+
+Return the current battery level.
+
+```sig
+brick.batteryLevel();
+```
+
+## Returns
+
+* a [number](/types/number) which is the current charge level of the brick's battery. This is a percentage of total charge left in the battery.
+
+## Example
+
+Show the battery level percentage on the screen. Also, show a green light if the battery level is above 15%. If the battery level is below 15% but above 5%, show a orange light. But, if the battery level is below 5%, show a pulsing red light.
+
+```blocks
+let battery = 0;
+forever(function() {
+    brick.showString("Battery level:", 1)
+    brick.showNumber(battery, 2)
+    battery = brick.batteryLevel();
+    if (battery > 15)
+    {
+        brick.setStatusLight(StatusLight.Green);
+    } else if (battery > 5) {
+        brick.setStatusLight(StatusLight.Orange);
+    } else {
+        brick.setStatusLight(StatusLight.RedPulse)
+    }
+    pause(30000)
+})
+```

docs/reference/brick/button/is-pressed.md

@@ -0,0 +1,53 @@
+# is Pressed
+
+Check if a button is being pressed or not.
+
+```sig
+brick.buttonEnter.isPressed()
+```
+
+## ~hint
+
+**Touch sensors**
+
+Your @boardname@ has touch sensors that work like buttons. Instead of saying `enter` or `left` as the source button, use a touch sensor block with a sensor name like `touch 1`.
+
+```block
+if (sensors.touch1.isPressed()) {
+    console.log("Hey, I feel pressed.");
+}
+```
+
+Read about [touch sensors](/reference/sensors/touch-sensor) and using them as touch buttons.
+
+## ~
+
+## Returns
+
+* a [boolean](types/boolean): `true` if the button is pressed, `false` if the button is not pressed
+
+## Example
+
+Set the brick light to green when the `down` is pressed. When the button is not pressed, the brick light is red.
+
+```blocks
+let isRed = false;
+forever(function() {
+    if (brick.buttonLeft.isPressed()) {
+        brick.setStatusLight(StatusLight.Green);
+        isRed = false;
+    } else {
+        if (!isRed) {
+            brick.setStatusLight(StatusLight.Red);
+            isRed = true;
+        }
+    }
+})
+```
+
+## See also
+
+[was pressed](/reference/brick/button/was-pressed),
+[on event](/reference/brick/button/on-event)
+
+[Touch sensors](/reference/sensors/touch-sensor)

docs/reference/brick/button/on-event.md

@@ -0,0 +1,57 @@
+# on Event
+
+Run some code when a button is clicked, pressed down, or released.
+
+```sig
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+
+});
+```
+
+## ~hint
+
+**Touch sensors**
+
+Your @boardname@ has touch sensors that work like buttons. Instead of saying `enter` or `left` as the source button, use a touch sensor block with a sensor name like `touch 1`.
+
+```block
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
+    brick.setStatusLight(StatusLight.Orange);
+});
+```
+
+Read about [touch sensors](/reference/sensors/touch-sensor) and using them as touch buttons.
+
+## ~
+
+## Parameters
+
+* **ev**: the button action to run some code for. The button actions (events) are:
+> * ``click``: button was clicked (pressed and released)
+> * ``up``: button is released from just being pressed
+> * ``down``: button is just pressed down
+* **body**: the code you want to run when something happens with a button
+
+## Example
+
+Check for event on the ENTER button. Put a message on the screen when the button is pressed, clicked, or released.
+
+```blocks
+brick.showString("ENTER is: UP", 1);
+brick.buttonEnter.onEvent(ButtonEvent.Released, function () {
+    brick.showString("ENTER is: UP      ", 1);
+});
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    brick.showString("ENTER is: DOWN    ", 1);
+});
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    brick.showString("ENTER was: CLICKED", 1);
+});
+```
+
+### See also
+
+[is pressed](/reference/brick/button/is-pressed),
+[was pressed](/reference/brick/button/was-pressed),
+
+[Touch sensor](/reference/sensors/touch-sensor)

docs/reference/brick/button/pause-until.md

@@ -0,0 +1,37 @@
+# pause Until
+
+Causes your program to wait until an event at a button happens.
+
+```sig
+brick.buttonEnter.pauseUntil(ButtonEvent.Bumped);
+```
+
+## Parameters
+
+* **ev**: the button action to wait for. The button actions (events) are:
+> * ``click``: button was clicked (pressed and released)
+> * ``up``: button is released from just being pressed
+> * ``down``: button is just pressed down
+
+## Example
+
+Wait for the `up` button to go up before continuing with displaying a message on the screen.
+
+```blocks
+let waitTime = 0;
+brick.showString("We're going to wait", 1);
+brick.showString("for you to press and", 2);
+brick.showString("release the UP button", 3);
+waitTime = control.millis();
+brick.buttonUp.pauseUntil(ButtonEvent.Bumped);
+brick.clearScreen();
+if (control.millis() - waitTime > 5000) {
+    brick.showString("Ok, that took awhile!", 1)
+} else {
+    brick.showString("Ah, you let go!", 1)
+}
+```
+
+## See also
+
+[on event](/reference/brick/button/on-event)

docs/reference/brick/button/was-pressed.md

@@ -0,0 +1,49 @@
+# was Pressed
+
+Check if a button was pressed earlier.
+
+```sig
+brick.buttonEnter.wasPressed()
+```
+
+The fact that a button was pressed earlier is remembered. Once **was pressed** is used, this fact is forgotten and the result is `false` the next time you check with **was pressed** button _state_ is reset). But, if you press the button again before you check with **was pressed**, it will tell you `true`. 
+
+## ~hint
+
+**Touch sensors**
+
+Your @boardname@ has touch sensors that work like buttons. Instead of saying `enter` or `left` as the source button, use a touch sensor block with a sensor name like `touch 1`.
+
+```typescript
+if (sensors.touch1.wasPressed()) {
+    console.log("Hey, I was pressed.");
+}
+```
+
+Read about [touch sensors](/reference/sensors/touch-sensor) and using them as touch buttons.
+
+## ~
+
+## Returns
+
+* a [boolean](types/boolean): `true` if the button was pressed before, `false` if the button was not pressed before
+
+## Example
+
+Set the brick light to green if the `right` button was pressed before the `left` button. If not, the brick light is turned off when the `left` button is pressed.
+
+```typescript
+brick.buttonLeft.onEvent(ButtonEvent.Bumped, function() {
+    if (brick.buttonRight.wasPressed()) {
+        brick.setStatusLight(StatusLight.Green)
+    } else {
+        brick.setStatusLight(StatusLight.Off)
+    }
+})
+```
+
+## See also
+
+[is pressed](/reference/brick/button/is-pressed),
+[on event](/reference/brick/button/on-event),
+[Touch sensors](/reference/sensors/touch-sensor)

docs/reference/brick/clear-screen.md

@@ -0,0 +1,22 @@
+# clear Screen
+
+Clear any text or numbers displayed on the screen. The screen will be blank.
+
+```sig
+brick.clearScreen();
+```
+
+## Example
+
+Clear the screen after displaying the message.
+
+```blocks
+brick.showString("This message will", 1);
+brick.showString("self-destruct in:", 2);
+brick.showString("seconds", 5);
+for (let i = 0; i < 10; i++) {
+    brick.showNumber(10 - i, 4);
+    pause(1000);
+}
+brick.clearScreen();
+```

docs/reference/brick/set-status-light.md

@@ -0,0 +1,37 @@
+# set Light
+
+Set the light on the brick to a solid or flashing color.
+
+```sig
+brick.setStatusLight(StatusLight.Red);
+```
+## Parameters
+
+* **pattern**: the color or color pattern for the brick light to show. The brick light can have these color patterns:
+>* `off`: brick light is off
+>* `green`: solid green
+>* `red`: solid red
+>* `orange`: solid orange
+>* `green flash`: flashing green
+>* `red flash`: flashing red
+>* `orange flash`: flashing orange
+>* `green pulse`: pulsing green
+>* `red pulse`: pulsing red
+>* `orange pulse`: pulsing orange
+
+## Example
+
+Repeatedly show a different color pattern for the brick light.
+
+```blocks
+forever(function () {
+    brick.setStatusLight(StatusLight.Orange)
+    pause(1000)
+    brick.setStatusLight(StatusLight.GreenFlash)
+    pause(2000)
+    brick.setStatusLight(StatusLight.RedPulse)
+    pause(2000)
+    brick.setStatusLight(StatusLight.Off)
+    pause(500)
+})
+```

docs/reference/brick/show-image.md

@@ -0,0 +1,24 @@
+# show Image
+
+Show an image on the brick's display.
+
+```sig
+brick.showImage(images.expressionsBigSmile);
+```
+You can choose one of several images to show on the display. 
+
+## Parameters
+
+**image**: A image to show on the brick's display. Use the image picker to choose the image you want to show.
+
+## Example
+
+Show a sleeping image on the brick's display.
+
+```blocks
+brick.showImage(images.expressionsZzz)
+```
+
+## See also
+
+[show image](/reference/brick/show-mood)

docs/reference/brick/show-number.md

@@ -0,0 +1,24 @@
+# show Number
+
+Show a number on the screen at the line you select.
+
+```sig
+brick.showNumber(0, 1);
+```
+
+## Parameters
+
+* **value**: a [number](/types/number) to show on the brick's screen.
+* **line**: The line number on the screen where the value is displayed. The line numbers for the screen start with line `1`.
+
+## Example
+
+Show the number `1000` on the screen.
+
+```blocks
+brick.showNumber(1000, 1);
+```
+
+## See also
+
+[show string](/reference/brick/show-string), [show value](/reference/brick/show-value)

docs/reference/brick/show-ports.md

@@ -0,0 +1,24 @@
+# show Ports
+
+Show the status of everything connected to the ports.
+
+```sig
+brick.showPorts()
+```
+
+You can find out what's connected to the ports on the brick and show its status. The status information from each sensor or motor connected is displayed on the screen.
+
+## Example
+
+Show the status of the ports on the brick when the ``enter`` button is pressed.
+
+```blocks
+brick.showString("Press ENTER for port status", 1)
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    brick.showPorts()
+})
+```
+
+## See also
+
+[show string](/reference/brick/show-string), [show value](/reference/brick/show-value)

docs/reference/brick/show-string.md

@@ -0,0 +1,29 @@
+# show String
+
+Show some text on a the screen at the line you select.
+
+```sig
+brick.showString("Hello world", 1)
+```
+
+## Parameters
+
+* **text**: a [string](/types/string) to show on the brick's screen.
+* **line**: the line [number](/types/number) on the screen where the text is displayed. The line numbers for the screen start with line `1`.
+
+## Example
+
+Show a greeting on the screen. Then, respond with another message when ENTER is pressed.
+
+```blocks
+brick.showString("Hello, I dare you to", 1);
+brick.showString("press ENTER...", 2);
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+	brick.showString("Hey! Don't push my", 4);
+	brick.showString("buttons.", 5);
+});
+```
+
+## See also
+
+[show number](/reference/brick/show-number)

docs/reference/brick/show-value.md

@@ -0,0 +1,29 @@
+# show Value
+
+Show a name-value-pair on the screen at the line you select.
+
+```sig
+brick.showValue("item", 0, 1);
+```
+
+Name-value-pairs are used to report data values to the screen. If you want to show the current temperature on the screen, you might use `"temp"` as the data name for the the value.
+
+## Parameters
+
+* **name**: a [string](/types/string) which is the name of the data value.
+* **value**: a [number](/types/number) to show on the brick's screen.
+* **line**: The line number on the screen where the value is displayed. The line numbers for the screen start with line `1`.
+
+## Example
+
+Show the current amount of ambient light detected by sensor 2.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Bumped, function () {
+    brick.showValue("color", sensors.color2.light(LightIntensityMode.Ambient), 1)
+})
+```
+
+## See also
+
+[show number](/reference/brick/show-number)

docs/reference/console.md

@@ -0,0 +1,15 @@
+# Console
+
+Output text and data values to the console.
+
+```cards
+console.log("");
+console.logValue("x", 0);
+console.sendToScreen();
+```
+
+## See also
+
+[log](/reference/console/log),
+[log value](/reference/console/log-value),
+[send to screen](/reference/console/send-to-screen)

docs/reference/console/send-to-screen.md

@@ -0,0 +1,26 @@
+# send To Screen
+
+Direct the console output to go to the @boardname@ screen.
+
+```sig
+console.sendToScreen();
+```
+
+A "console" is a place for a user to see special messages from a device. It could be  something connected to a serial port, a display that shows text, or even a text file. A console is typically used as a place to send information that is added to a message _log_ (a record of messages that are sent from a device). Your program can send log messages using the [console](/reference/console) functions. The MakeCode editor has a console view that lets you see the console output when your program runs in the simulator.
+
+On the @boardname@, the screen can serve as a console too and you can make your console output go there. Before using the console log functions, set the screen as the console output location.
+
+## Example
+
+Direct the console output to go to the screen. Show 20 values on the screen. Use the up and down buttons to scroll through the values.
+
+```blocks
+console.sendToScreen()
+for (let index = 0; index <= 20; index++) {
+    console.logValue("index", index)
+}
+```
+
+## See also
+
+[log](reference/console/log), [log value](/reference/console/log-value)

docs/reference/control.md

@@ -0,0 +1,33 @@
+# Control
+
+Program controls and events.
+
+```cards
+control.millis();
+control.runInParallel(() => {
+    
+});
+control.reset();
+control.waitMicros(4);
+control.deviceSerialNumber();
+```
+
+## Timer
+
+```cards
+control.timer1.reset()
+control.timer1.pauseUntil(5)
+control.timer1.millis()
+control.timer1.seconds()
+```
+
+## Advanced #advanced
+
+```cards
+control.raiseEvent(0, 0);
+control.onEvent(0, 0, () => {
+    
+});
+control.assert(false, 0);
+control.panic(0);
+```

docs/reference/control/assert.md

@@ -0,0 +1,12 @@
+# @extends
+
+## Example #example
+
+Stop the program if the gyro dectects an angle greater than 45 degrees.
+
+```blocks
+forever(function () {
+    control.assert(sensors.gyro2.angle() > 45, 15)
+    pause(300)
+})
+```

docs/reference/control/device-serial-number.md

@@ -0,0 +1,9 @@
+# @extends
+
+## Example #example
+
+Log the device serial number to the console.
+
+```blocks
+console.logValue("serialnumber", control.deviceSerialNumber());
+```

docs/reference/control/on-event.md

@@ -0,0 +1,25 @@
+# @extends
+
+# Example #example
+
+Register two events coming from source `22`. Make the brick status light up  when
+the events of `0` and `1` are _raised_.
+
+```blocks
+const statusLighter = 22;
+
+control.runInParallel(() => {
+    for (let i = 0; i < 2; i++) {
+        pause(1000);
+        control.raiseEvent(statusLighter, i);
+    }
+})
+
+control.onEvent(statusLighter, 0, () => {
+    brick.setStatusLight(StatusLight.OrangePulse)
+})
+
+control.onEvent(statusLighter, 1, () => {
+    brick.setStatusLight(StatusLight.GreenPulse)
+})
+```

docs/reference/control/panic.md

@@ -0,0 +1,13 @@
+# @extends
+
+## Example #example
+
+Send a 'code red' error that you created to the error display if the brick crashes into a wall.
+
+```blocks
+let codeRed = 1
+let codeBlue = 2
+sensors.touch1.onEvent(ButtonEvent.Pressed, function () {
+    control.panic(codeRed)	
+})
+```

docs/reference/control/raise-event.md

@@ -0,0 +1,25 @@
+# @extends
+
+# Example #example
+
+Register two events coming from source `22`. Make the brick status light up  when
+the events of `0` and `1` are _raised_.
+
+```blocks
+const statusLighter = 22;
+
+control.runInParallel(() => {
+    for (let i = 0; i < 2; i++) {
+        pause(1000);
+        control.raiseEvent(statusLighter, i);
+    }
+})
+
+control.onEvent(statusLighter, 0, () => {
+    brick.setStatusLight(StatusLight.OrangePulse)
+})
+
+control.onEvent(statusLighter, 1, () => {
+    brick.setStatusLight(StatusLight.GreenPulse)
+})
+```

docs/reference/control/run-in-parallel.md

@@ -0,0 +1,61 @@
+# @extends
+
+## Separate tasks #tasks
+
+As an example, you could have a small task that checks the battery level and gives a warning when it drops below 15 percent. This is placed inside a ``||control:run in parallel||`` block:
+
+```block
+let powerCheck = false;
+
+control.runInParallel(() => {
+    while (!powerCheck) {
+        if (brick.batteryLevel() <= 15) {
+            brick.setStatusLight(StatusLight.RedFlash)
+            powerCheck = true;
+        } else {
+            pause(5000);
+        }
+    }
+})
+```
+
+The code the main program just drives the brick in a constant pattern until the battery check in the parallel task says that the battery level is too low.
+
+```block
+let powerCheck = false;
+while (!powerCheck) {
+    motors.largeBC.tank(50, 50, 5, MoveUnit.Seconds)
+    motors.largeBC.steer(5, 50, 6, MoveUnit.Rotations)
+}
+motors.stopAll()
+```
+
+## #example
+
+Tank the brick in a pattern until the battery warning variable is set. Have a separate task check the battery level and set a warning variable when the level is below `5` percent.
+
+```blocks
+let powerCheck = false;
+
+control.runInParallel(() => {
+    while (!powerCheck) {
+        if (brick.batteryLevel() < 5) {
+            powerCheck = true;
+        } else {
+            pause(5000);
+        }
+    }
+})
+
+while (!powerCheck) {
+    motors.largeBC.tank(20, 20, 5, MoveUnit.Seconds)
+    motors.largeBC.steer(15, 20, 6, MoveUnit.Rotations)
+    motors.largeBC.tank(40, 40, 5, MoveUnit.Seconds)
+    motors.largeBC.steer(-10, 20, 3, MoveUnit.Rotations)
+}
+motors.stopAll()
+```
+
+## See also #seealso
+
+[forever](/reference/loops/forever)

docs/reference/control/timer.md

@@ -0,0 +1,8 @@
+# Timer
+
+```cards
+control.timer1.reset()
+control.timer1.pauseUntil(5)
+control.timer1.millis()
+control.timer1.seconds()
+```

docs/reference/control/timer/millis.md

@@ -0,0 +1,25 @@
+# millis
+
+Get the amount of time counted by the timer in milliseconds.
+
+The timer count begins from `0` when you program starts or is [reset](/reference/control/timer/reset). 
+
+## Returns
+
+* a [number](/types/number) that is the amount of time elapsed, in milliseconds, since the timer was started or reset.
+
+## Example
+
+Find out how many milliseconds go by between presses of the `down` button on the brick.
+
+```blocks
+brick.buttonDown.onEvent(ButtonEvent.Pressed, function () {
+    brick.showValue("DownButtonTime", control.timer1.millis(), 1)
+    control.timer1.reset()
+})
+```
+
+## See also
+
+[seconds](/reference/control/timer/seconds), [reset](/reference/control/timer/reset)
+

docs/reference/control/timer/pause-until.md

@@ -0,0 +1,32 @@
+# pauseUntil
+
+Pause until the timer counts up to a number of milliseconds.
+
+```sig
+control.timer1.pauseUntil(0)
+```
+
+When code in a block comes to a **pauseUntil**, it will wait until the timer count reaches the number of milliseconds you say. Code in blocks like **forever** and **runInParallel** will keep running while the current code is paused.
+
+The time number you give is the number of milliseconds past the running timer count. If the timer is currently at `25000` milliseconds and you want to pause for `10` seconds, then use a pause time of `35000`. If you want your pause time number to match the actual wait time, then [reset](/reference/control/timer/reset) the timer first.
+
+## Parameters
+
+* **ms**: the [number](/types/number) of milliseconds that you want the timer to count up to. For seconds, convert to milliseconds: 100 milliseconds = 1/10 second and 1000 milliseconds = 1 second.
+
+## Example
+
+Pause between messages on the screen by `5` seconds.
+
+```blocks
+brick.clearScreen()
+brick.showString("Testing my pause...", 1)
+let startTime = control.timer1.millis()
+brick.showValue("StartTime", startTime, 3)
+control.timer1.pauseUntil(startTime + 5000)
+brick.showValue("EndTime", control.timer1.millis() - startTime, 4)
+```
+
+## See also
+
+[millis](/reference/control/timer/millis), [reset](/reference/control/timer/reset)

docs/reference/control/timer/reset.md

@@ -0,0 +1,49 @@
+# reset
+
+Reset the elapsed time of the timer back to `0`.
+
+```sig
+control.timer1.reset()
+```
+
+A timer starts counting from `0` when your program starts. It's time value always gets larger as your program runs. Maybe you want to meausure how long some task takes to finish or you want to do some action  only for a little while. A timer can keep track of the time it takes to do it.
+
+Resetting the timer sets the time value to `0` so the next time you check the time it's exactly the amount of time that has _elapsed_. Otherwise, you need to remember a start time value and then subtract it from the current time. 
+
+## Examples
+
+### Press time
+
+Find out how much time goes by between presses of the `enter` button on the brick.
+
+```blocks
+brick.buttonEnter.onEvent(ButtonEvent.Pressed, function () {
+    brick.showValue("PressTime", control.timer1.seconds(), 1)
+    control.timer1.reset()
+})
+```
+
+### Difference timer
+
+Use a difference timer and compare it to a timer that resets. Use the ``left`` button to start timing and the ``right`` button to stop.
+
+```blocks
+let startTime = 0
+let timing = false
+brick.buttonLeft.onEvent(ButtonEvent.Pressed, function () {
+    brick.clearScreen()
+    brick.showString("Starting timers...", 1)
+    startTime = control.timer1.seconds()
+    control.timer2.reset()
+    timing = true
+})
+brick.buttonRight.onEvent(ButtonEvent.Pressed, function () {
+    if (timing) {
+        brick.clearScreen()
+        brick.showString("Timer results...", 1)
+        brick.showValue("timer 1", control.timer1.seconds() - startTime, 3)
+        brick.showValue("timer 2", control.timer2.seconds(), 4)
+        timing = false;
+    }
+})
+```

docs/reference/control/timer/seconds.md

@@ -0,0 +1,25 @@
+# seconds
+
+Get the amount of time counted by the timer in seconds.
+
+The timer count begins from `0` when you program starts or is [reset](/reference/control/timer/reset). The number of seconds returned also includes milliseconds if there is a fractional part of a second too.
+
+## Returns
+
+* a [number](/types/number) that is the amount of time elapsed, in seconds, since the timer was started or reset.
+
+## Example
+
+Find out how many seconds go by between presses of the `down` button on the brick.
+
+```blocks
+brick.buttonDown.onEvent(ButtonEvent.Pressed, function () {
+    brick.showValue("DownButtonTime", control.timer1.seconds(), 1)
+    control.timer1.reset()
+})
+```
+
+## See also
+
+[millis](/reference/control/timer/millis), [reset](/reference/control/timer/reset)
+

docs/reference/control/wait-micros.md

@@ -0,0 +1,17 @@
+# @extends
+
+## Example #example
+
+Use the a wait and the timer to generate a crazy number.
+
+```blocks
+let crazy = 0
+for (let i = 0; i < 100; i++) {
+    control.waitMicros(100)
+    crazy = control.millis()
+    crazy += control.deviceSerialNumber()
+    if (crazy != 0) {
+        crazy = crazy / 1000000
+    }
+}
+```

docs/reference/motors.md

@@ -0,0 +1,23 @@
+# Motors
+
+## Motion
+
+```cards
+motors.largeA.run(50)
+motors.largeAB.tank(50, 50)
+motors.largeAB.steer(0, 50)
+motors.largeA.pauseUntilReady()
+motors.largeA.setBrake(false)
+motors.largeA.setInverted(true)
+motors.largeA.setRegulated(false)
+motors.largeA.stop()
+motors.largeA.reset()
+motors.stopAll()
+```
+## Counters
+
+```cards
+motors.largeA.speed()
+motors.largeA.angle()
+motors.largeA.clearCounts()
+```

docs/reference/motors/motor/angle.md

@@ -0,0 +1,31 @@
+# angle
+
+Get the current angle of the motor's rotation in degrees.
+
+```sig
+motors.largeA.angle()
+```
+
+When a motor is started for the first time, or after a reset, it's angle of rotation starts at `0` degrees. A complete rotation (a turn in a full circle) is `360` degrees. At `360` degrees, the motor angle doesn't go back to `0` but keeps counting in degrees. So, one and a half turns adds up to `540` degrees of total rotation.
+
+## Returns
+
+* a [number](/types/number) which is the current angle of rotation for the motor.
+
+## Example
+
+Reset the motor connected to port **A** and run it for for 2 seconds at a speed of `45`. Stop and get the current angle of rotation.
+
+```blocks
+let motorAngle = 0;
+motors.largeA.reset()
+motors.largeA.run(45)
+pause(2000)
+motors.largeA.stop()
+motorAngle = motors.largeA.angle()
+```
+
+## See also
+
+[speed](/reference/motors/motor/speed),
+[reset](/reference/motors/motor/reset), [clear counts](/reference/motors/motor/clear-counts)

docs/reference/motors/motor/clear-counts.md

@@ -0,0 +1,35 @@
+# clear Counts
+
+Set all counters for the motor back to zero.
+
+```sig
+motors.largeA.clearCounts()
+```
+
+The counters for a motor are: **tacho**, **angle**, and **speed**. Each of these counters is set to start counting from `0` again. This is a way to begin new counts without having to reset the motor.
+
+## Example
+
+See if the motor turns the same number of times for each of two count periods. Run the motor connected to port **A** twice for 10 seconds and compare the tacho counts.
+
+```blocks
+let tachoCount = 0;
+motors.largeA.reset()
+motors.largeA.run(50)
+pause(10000)
+tachoCount = motors.largeA.angle()
+motors.largeA.clearCounts()
+motors.largeA.run(50)
+pause(10000)
+if (tachoCount == motors.largeA.angle()) {
+    brick.showString("Motor turns equal.", 1)
+} else {
+    brick.showString("Motor turns NOT equal.", 1)
+}
+motors.largeA.stop()
+```
+
+## See also
+
+[angle](/reference/motors/motor/angle),
+[speed](/reference/motors/motor/speed), [reset](/reference/motors/motor/reset)

docs/reference/motors/motor/reset.md

@@ -0,0 +1,30 @@
+# reset
+
+Reset the motor's speed setting and it's counters.
+
+```sig
+motors.largeA.reset()
+```
+
+The motor's speed is set back to `0` and the **tacho**, **angle**, and **speed** counters are set to `0`.
+
+## Example
+
+See what the angle count is when a motor is stopped. Then, try it again after a reset.
+
+```blocks
+motors.largeA.run(30)
+pause(2000)
+motors.largeA.stop()
+brick.showString("Angle count:", 1)
+brick.showNumber(motors.largeA.angle(), 2)
+motors.largeA.run(30)
+pause(2000)
+motors.largeA.reset()
+brick.showString("Angle count:", 4)
+brick.showNumber(motors.largeA.angle(), 5)
+```
+
+## See also
+
+[stop](/reference/motors/motor/stop), [clear counts](/reference/motors/motor/clear-counts)

docs/reference/motors/motor/run.md

@@ -0,0 +1,96 @@
+# run
+
+Set the rotation speed of the motor as a percentage of maximum speed.
+
+```sig
+motors.largeA.run(50)
+```
+
+The speed setting is a pecentage of the motor's full speed. Full speed is the speed that the motor runs when the brick supplies maximum output voltage to the port.
+
+If you use just the **speed** number, the motor runs continously and won't stop unless you tell it to. You can also give a value for a certain amount of distance you want the motor to rotate for. The **value** can be an amount of time, a turn angle in degrees, or a number of full rotations.
+
+If you decide to use a **value** of rotation distance, you need to choose a type of movement **unit**.
+
+## ~hint
+
+If you use a number of milliseconds as movement units, then you don't need to include the unit type.
+
+To run the motor for 500 milliseconds:
+
+```block
+motors.largeA.run(50, 500)
+```
+
+## ~
+
+Here is how you use each different movement unit to run the motor for a fixed rotation distance.
+
+```blocks
+// Run motor for 700 Milliseconds. 
+motors.largeA.run(25, 700, MoveUnit.MilliSeconds);
+
+// Run motor for 700 Milliseconds again but no units specified. 
+motors.largeA.run(25, 700);
+
+// Run the motor for 45 seconds
+motors.largeA.run(50, 45, MoveUnit.Seconds);
+
+// Turn the motor for 270 degrees
+motors.largeA.run(50, 270, MoveUnit.Degrees)
+
+// Turn the motor at full speed for 9 full rotations
+motors.largeA.run(100, 9, MoveUnit.Rotations);
+```
+
+## Parameters
+
+* **speed**: a [number](/types/number) that is the percentage of full speed. A negative value runs the motor in the reverse direction.
+* **value**: the [number](/types/number) of movement units to rotate for. A value of `0` means run the motor continuously.
+* **unit**: the movement unit of rotation. This can be `milliseconds`, `seconds`, `degrees`, or `rotations`. If the number for **value** is `0`, this parameter isn't used.
+
+## ~hint
+
+** Reverse is negative speed**
+
+Turning the motor in the opposite direction (reverse) is simple. Reverse is just a negative speed setting. To drive the motor in reverse at 25% speed:
+
+```block
+motors.largeB.run(-25)
+```
+
+## ~
+
+## Examples
+
+### Drive the motor for 20 seconds
+
+Run the motor connected to port **A** continuously. Pause 20 seconds and then stop the motor.
+
+```blocks
+motors.largeA.run(75)
+pause(20000)
+motors.largeA.stop()
+```
+
+### Backwards motion
+
+Run the motor connected to port **A** in reverse. Pause 5 seconds and then stop the motor.
+
+```blocks
+motors.largeA.run(-60)
+pause(5000)
+motors.largeA.stop()
+```
+
+### Run the motor for 35 rotations
+
+Run the motor connected to port **B** for 35 full rotations and then stop.
+
+```blocks
+motors.largeB.run(50, 35, MoveUnit.Rotations)
+```
+
+## See also
+
+[tank](/reference/motors/synced/tank), [steer](/reference/motors/synced/steer), [stop](/reference/motors/motor/stop)

docs/reference/motors/motor/set-brake.md

@@ -0,0 +1,30 @@
+# set Brake
+
+Set the brake on the motor so it won't turn when it has no power.
+
+```sig
+motors.largeA.setBrake(false)
+```
+
+When a the motor is stopped, it can still rotate if an external force is applied to it. This can happen, for example, if your're tanking your brick on a inclined surface and stop the motors. Gravity will push down on the brick and might cause it to start rolling again. You can prevent this movement by setting the brake.
+
+Also, you can use the brake to do simple skid steering for your brick.
+
+## Paramters
+
+* **brake**: a [boolean](/types/boolean) value which is either `true` to set the brake on or `false` to set the brake off.
+
+## Example
+
+Run the motor connected to port **A** for 2 seconds at a speed of `30`. Stop and set the brake.
+
+```blocks
+motors.largeA.run(30)
+pause(2000)
+motors.largeA.stop()
+motors.largeA.setBrake(true)
+```
+
+## See also
+
+[stop](/reference/motors/motor/stop)

docs/reference/motors/motor/set-inverted.md

@@ -0,0 +1,32 @@
+# set Reversed
+
+Change the direction of rotation for a motor.
+
+```sig
+motors.largeA.setInverted(true)
+```
+
+You use a positive value (some number greater than `0`) to drive you motor in the default direction. If you're using a motor in a way that makes more sense for your program to use a negative speed setting for that direction, you can reverse the speed range.
+
+## Paramters
+
+* **reversed**: a [boolean](/types/boolean) value that is `false` if the motor will use a speed value between `0` and `100` to turn in the default direction. If `true`, the motor uses a speed value between `0` and `-100` to turn in the default direction.
+
+## Example
+
+Run the motor connected to port **A** for 2 seconds at a speed of `30`. Stop and switch the direciton of rotation. Run the motor at a speed of `-30`. Watch and see if the motor turns in the same direction as before.
+
+```blocks
+motors.largeA.run(30)
+pause(2000)
+motors.largeA.stop()
+pause(2000)
+motors.largeA.setInverted(true)
+motors.largeA.run(-30)
+pause(2000)
+motors.largeA.stop()
+```
+
+## See also
+
+[stop](/reference/motors/motor/stop)

docs/reference/motors/motor/set-regulated.md

@@ -0,0 +1,32 @@
+# set Regulated
+
+Tell a motor to regulate its speed or not.
+
+```sig
+motors.largeA.setRegulated(true)
+```
+
+In order for a motor to always rotate at a constant speed it needs regulation. This means that the motor control electronics need to continously measure how much rotation has happened. The controller takes several rotation counts for a small amount of time and compares them to see if the speed is changing. The output power is adjusted if the controller detects that the motor is running too slow or too fast.
+
+If it's not regulated, your motor can change from the speed that you've set for it. Some examples are if your brick is driving forward and bumps into an object or it drives up a slope creating more load on the motor. In theses situations, if your motor speed is regulated, the controller will boost the power to the motor to keep it's speed from slowing down. Another example is when you run the motors to drive your brick down a slope. In this case, the motors would go faster than the speed you set for them if not regulated. To regulate this the controller reduces the power output to the motors to keep the brick from going faster.
+
+Motor regulation is always set to **ON** when your program first starts or the motor is reset.
+
+## Paramters
+
+* **value**: a [boolean](/types/boolean) value which means that the motor speed is regulated if `true`. The motor speed is not regulated when this is `false`.
+
+## Example
+
+Turn off the speed regulation for the motor connected to port **A**.
+
+```blocks
+motors.largeA.setRegulated(false)
+motors.largeA.run(75)
+pause(20000)
+motors.largeA.stop()
+```
+
+## See also
+
+[run](/reference/motors/motor/run), [stop](/reference/motors/motor/stop)