pxt-calliope/docs/projects/guitar/lightsensor.md
Abhijith Chatra be7858cbed
Cherry picked fixes from v0 to v1 (#1476)
* Fix example and do a few edits (#850)

* Small fixes to the Karel project text (#862)

* fix missing shadow type

* add calibration info (#897)

microbit-support:6348 User reported bug, but didn't realie micro:bit compass had to be calibrated on first run of the program.

* Cherry pick adding various cross-editor compat APIs (#863)

* fix nudge

* Fix a typo ("screent") in the documentation (#1012)

* Fix a typo
"screent" -> "the LED screen"

* Update showArrow doc string for consistency with other methods

* Doc bugs found by xlators (#899)

* Update rotation.md (#998)

reflects actual behaviour of the board

* fixed layout corruption (#1073)

* Updating the new bug filer with the right link

* Update challenges.md (#1325)

For what I'm taught in school, 2 follows 1 😉😉.

* Update simulator.md (#1209)

* Update plant watering.md (#1264)

the connection to servo are male not female

* support for MIDI simulator in v0 (#1331)

* Doc improvements (#1337)

* update grammar in radio-dashboard sample code

* Chanllenge 2 follows 1

I open all challenges.md without "Challenge 2" and review the file
`grep -r "Challenge 2" -L | grep challenge | xargs -I@ code @`

Changes to be committed:
	modified:   docs/lessons/counter/challenges.md
	modified:   docs/lessons/game-counter/challenges.md
	modified:   docs/lessons/night-light/challenges.md
	modified:   docs/lessons/snowflake-fall/challenges.md

* Revert "support for MIDI simulator in v0 (#1331)"

This reverts commit 30a9c411fb80762656e7a636feff8e77b7fd9e67.

* Revert "Cherry pick adding various cross-editor compat APIs (#863)"

This reverts commit 7308dbef23e9ee402bebb7e721d7014d8252c9e5.

* Fixed pin needed to replace button A (#1385)

* Cherry pick part of the signature update in in2cWriteBuffer (#863): 7308dbe
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Markdown

# Light Sensor Tone control
## @description @boardname@ guitar: using light sensor to control tone
## ~avatar avatar
Use the Light Sensor to the control tone for this [Theremin](https://en.wikipedia.org/wiki/Theremin) inspired guitar
* **Concepts:**
* Inputs
* Light Intensity
* Tone/Frequency
* Ratio Mapping
* Forever Loop
* Math (multiplication) with code properties
## ~
## Duration: 30 - 45 minutes
*playing tones with light sensor*
https://youtu.be/2cKg9pokVC4
## The @boardname@ LEDs Light Sensors
- the @boardname@ can detect external light level intensity reaching the LEDs
- the light level block reports a reading of values 0 (*dark*) to 255 (*bright*)
- a **Forever Loop** is required to continually measure the current light level and control the tone
## Forever Loop
The forever loop really does run forever. The forever loop is useful when there is a need to continually check for an event or use a changing value in code.
## Blocks
```cards
basic.forever(() => {})
input.lightLevel()
led.plotBarGraph(0, 255)
music.playTone(Note.C, music.beat(BeatFraction.Quarter))
```
## Step 1: Create a light level detector
```blocks
basic.forever(() => {
led.plotBarGraph(input.lightLevel(), 255)
})
```
**Build the blocks**
* From **Basic** drag a **forever loop** block into the coding area
* From **Led** drag a **plot bar graph** block into the **forever loop**
* From **Input** drag a **light level** block into **plot bar graph *of***
**Set the *plot bar graph* value *up to* = *255* **
## Step 2: Test the light required to move the bar graph height
*graphing light input*
https://youtu.be/pqU7bTcfQ_s
Experiment to see the effect on graph height when the **plot bar graph** value ***up to*** is changed
**255 is the maximum light input reading**, try numbers smaller than 255
**Find a value** that allows the graph to show 1 - 5 bars
## ~hint
## Frequency
**Frequency** measured in Hz which are cycles per second or vibrations per second
* A healthy human ear can detect frequencies in the range of 20Hz to 20,000Hz.
* The @boardname@ + headphones reliably produce detectable output ~50Hz - 6,000Hz.
**261Hz** represents a C note
```blocks
music.playTone(261, music.beat(BeatFraction.Half))
```
**play tone** blocks can specify a numeric **Frequency**
by replacing the letter **C** note with a **number** block that has the value it represents
```blocks
music.playTone(261, music.beat(BeatFraction.Half))
```
## ~
## Step 3: Multiply Frequency using Math blocks
```blocks
input.onButtonPressed(Button.A, () => {
music.playTone(261 * 2, music.beat(BeatFraction.Half))
})
```
Create a **play tone** block using a **Math** section, **multiplication** block to set *tone*
## Next
**Add** a **B** button block that multiplies the **261** tone by a number other than 2 to set tone
**Download the code to the @boardname@**
**Test the sound for multiples of the 261Hz *C* frequency**
## Step 4: Control the Frequency with the light input
```blocks
basic.forever(() => {
music.playTone(input.lightLevel() * 25, music.beat(BeatFraction.Quarter))
})
```
**Create a *forever loop* containing a *play tone* block**
**Set *tone*, using *Math* multiplication block that multiplies *light level* input by 25**
or experiment with multipliers larger and smaller than 25
**Test light tone control on the guitar**
Cover the LEDs with your hand to vary light detected to control the tone
## Good work, this guitar is sounding good!
**Challenge:** Create a variable for the light level multiplier that you can change using buttons (optional)
## ~button /projects/guitar/accelerometer
NEXT: Accelerometer Beat control
## ~