F15: Electronic Piano

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Grading Criteria

  • How well is Software & Hardware Design described?
  • How well can this report be used to reproduce this project?
  • Code Quality
  • Overall Report Quality:
    • Software Block Diagrams
    • Hardware Block Diagrams
      Schematic Quality
    • Quality of technical challenges and solutions adopted.

Electric Piano with Motion Controlled LED Keys

Top view of implemented board
Piano keys
Side view of implemented board
Top keys being played
Bottom keys being played

Abstract

The purpose of this project is to design and build a motion controlled electronic piano powered by an SJ-One Board. Users will be able to play the notes of a piano using IR proximity sensors as keys. At activation, the key's LED will light up. The number of keys of the piano will cover one key short of an octave; however, the piano provides users the capability to change (offset) the notes across other ranges.

Objectives & Introduction

The objective of this project is to design and build a multi-keyed motion controlled electronic piano. The piano will feature 12 IR proximity sensors to act as motion activated keys, a real-time MIDI decoder to play piano notes, and LEDs that activate along with the activation of its associated key. The electronic piano will utilize FreeRTOS multitasking environment to simultaneously sample values from multiple IR proximity sensors, analyze the obtained values, then play piano notes according to the active state of the IR keys.

1. Read an IR sensor's value using an external ADC

2. Write a software to read multiple IR sensors and play different piano notes using a MIDI decoder

3. Assemble a range of IR sensors to function as piano keys and an array of ADCs to read all IR sensors

4. Build a wooden frame and mount the control circuits and IR sensors

5. Integrate LEDs to each key and control the LEDs using an LED driver

Team Members & Responsibilities

  • Jason Tran
    • Design and write the software
    • Design and build the power circuit and ADC circuit
  • Arthur Nguyen
    • Design and build the wooden frame
    • Mount boards and IR keys onto the wooden frame
    • Design and build the LED circuit

Schedule

Show a simple table or figures that show your scheduled as planned before you started working on the project. Then in another table column, write down the actual schedule so that readers can see the planned vs. actual goals. The point of the schedule is for readers to assess how to pace themselves if they are doing a similar project.

Week# Date Task Actual
1 10/30 Project proposal Completed. Discussed project design of both hardware and software.
2 11/6 Part testing and project outline Completed testing Sharp IR sensor and MIDI controller interface.
3 11/13 Order parts Completed order of essential parts including VS1053, short IR sensors,IR jumper wires, and analog to digital converters. Completed software.
4 11/20 Setup all keys with sound. Completed playing sounds with key activation.
5 11/27 Volume control and power circuit. Completed.
6 12/4 Combine circuits and start mounting system. Ordered LEDs and LED driver. Started mounting system onto board.
7 12/11 Build LED circuit and implement software for LEDs. Combine circuits and mount rest of system onto board. Completed mounting circuit boards and wiring on 12/15. Final test completed on 12/16.
8 12/17 Final changes and demo Completed demo on 12/17.

Parts List & Cost

Give a simple list of the cost of your project broken down by components. Do not write long stories here.

Quanitity Price per part Part Detail Vendor
1 $80 SJ-One Board Microcontroller SJSU SCE
12 $13.95 GP2Y0A41SK0F Infrared Proximity Sensor Short Range-Sharp SparkFun
12 $1.50 3-pin JST Infrared Sensor Jumper Wire SparkFun
6 $2.30 MCP3002 Analog to Digital Converter SparkFun
12 $0.202 WP59EGW/CA Red/Green Diffused Common Anode LED Mouser
1 $1.48 TLC6C5912QPWRQ1 12 Channel Shift Register LED Driver Mouser
1 $5.42 LCQT-TSSOP20 TSSOP to 20DIP Socket Adapter Mouser
1 $19.95 VS1033D MIDI Decoder Breakout Board SparkFun
1 $1.95 LD1117V33 3.3 V voltage Regulator SparkFun
1 $1.50 PRT-08032 3.5 mm audio jack SparkFun
2 $1.25 PRT-09011 USB female type A speakers SparkFun
1 $13.00 AL-101 USB powered speakers Amazon
24 $0.04 150 Ohm resistor Fry's
Total $328.38

Design & Implementation

The design section can go over your hardware and software design. Organize this section using sub-sections that go over your design and implementation.

Hardware Design

Discuss your hardware design here. Show detailed schematics, and the interface here.

    Board Schematic
Top view schematic

The board schematic shown displays the precise measurement of the board as well as where the keys are placed on the board. Keys are also assigned 0 to 11. This assignments is referenced by the LED numbering and the ADC_Ch signal. LEDs are placed beneath the keys, with red LEDs associated to the top keys and green LEDs associated to the bottom keys.


    Power Circuit
Power circuit

The power circuit is powered by USB A which distributes the source to the SJ-One Board, to the 3V3 voltage regulator, and to another USB A connector intended to supply power to an external speaker. The 3V3 voltage regulator distributes power to the VS1033 MIDI decoder, to the ADC circuit, and to the LED driver. The power circuit also contains a 3.5mm audio out connector to direct the audio signal from the MIDI decoder to an external speaker. Additionally, the board contains an AC coupling circuit to remove the DC offset from the audio signal.


    SJ-One Board
SJ-One Board

First, the SJ-One Board is powered by the 5V and ground supplied by the power circuit.


    VS1033


    Analog to Digital Converter Circuit
Analog to digital converter circuit board

As seen, the MOSI, MISO, and CLK connections from the SJ-One Board connect to all of the analog to digital converter's Din, Dout, and CLK pins, respectively. 6 GPIO pins from the SJ-One Board are tied to each of the 6 CS pins of the analog to digital converters. VDD is connected to a 3.3 V source, while VREF is connected to ground for each ADC. Finally, the channels of the ADC are connected to the VO of the short IR sensors.


    LED Driver
LED driver circuit

As seen, Drain0 to Drain11 are connected to 150 Ohm resistors, which in turn, are connected to their corresponding numbered key LED cathodes. All LEDs have their anode connected to a 5 V source. LEDs 0, 1, 2, 3, 4, 5, and 7 have its green cathode connect to 150 Ohm resistors and then to ground in order to illuminate green color all the time. Likewise, LEDs 10, 11, 8, 9, and 6 have their cathodes connected to 150 Ohm resistors and then to ground in order to illuminate red color at all times. Drains 0, 1, 2, 3, 4, 5, and 7 are connected to 150 Ohm resistors and then to their corresponding LEDs' red cathode. Drains 10, 11, 8, 9, and 6 are connected to 150 Ohm resistors and then to their corresponding LEDs' green cathode. The GND and G pins are connected to ground, while the VCC and CLR pins are connected to 3.3 V source. The MOSI, CLK, and GPIO output pins from the SJ-One board are connected to the SER IN, SCK, and RCK pins of the LED driver.

Hardware Interface

SPI was used used to communicate with the ADC devices, the MIDI decoder, and the LED driver. Meanwhile, GPIO was used as control signals, such as chip select and output enable, for the MIDI decoder and the LED driver. In the software, the following SPI and GPIO driver were used to communicate to the IO devices.

SPI driver:

   namespace My_spi {
       void init_ssp1_spi( void );                   // Using SCK1, MISO1, MOSI1 (P0.7, P0.8, P0.9)
       void init_cs( uint8_t port, uint8_t pin );
       char spi_exchange_byte ( char byte );
       void cs_select( uint8_t port, uint8_t pin );
       void cs_deselect( uint8_t port, uint8_t pin );
   }

For the My_spi driver, the init_ssp1_spi() function initializes LPC1758 SSP controller to function as an SPI controller with the following setting: MSB first, 8-bit data frame, and 500 KHz clock while other settings remained default. The init_cs(port, pin) function initializes a given IO pin to function as a GPIO output used for chip select. cs_select(port, pin) and cs_deselect(port, pin) functions are used to activate and deactivate a given IO pin respectively. Lastly, spi_exchange_byte(byte) function clocks 8-bits to and from a SPI slave device; cs_select(port, pin) and cs_deselect(port, pin) should be called before and after the call of the SPI exchange function(s) to target a specific SPI slave device. Exception: The LED driver is a shift register and does not use chip select. Instead, a GPIO output is used to signal the shift register to update its output (LEDs).


GPIO driver:

   namespace My_gpio {
       void set_gpio_mode( uint8_t port, uint8_t pin, bool mode );
       void digital_write( uint8_t port, uint8_t pin, bool state );
       bool digital_read( uint8_t port, uint8_t pin );                     // Assuming active high input
   }

For the My_gpio driver, the set_gpio_mode(port, pin, mode) function initializes a given IO port to function as a specific GPIO mode (mode can be either input or output). The digital_write(port, pin, state) function sets a given GPIO pin to a given voltage level or state (voltage level can either be high or low). The digital_read(port, pin) function reads the voltage level of a given pin and returns a Boolean value (returns true if high and false if low).





In this section, you can describe how your hardware communicates, such as which BUSes used. You can discuss your driver implementation here, such that the Software Design section is isolated to talk about high level workings rather than inner working of your project.

Software Design

CMPE146 F15 ElectricPaino SoftwareArchitecture.png

For the software design, there are three tasks: MIDI task (consumer), IR Key task (producer) and Control task (producer). During the idle state, the consumer remains in sleep and waits for a command from the producers. When an action takes place such as an activation of a key or a button, the consumer immediately wakes and executes the received command. Commands and messages are passed using FreeRTOS queues.

The MIDI task is responsible for playing notes at a certain pitch and volume. The task also provides feedback of the current pitch (octave) and volume using the SJ-One Board’s 7 segment display and on-board LEDs.

The IR Key task is responsible for sampling the IR sensors by reading the values from the ADC. If a key is sampled as active, then the key’s LED turns on, the key’s note and the play note command are sent to the MIDI task. The opposite occurs when a key is deactivated when previously in the active state.

The Control task is responsible for reading user input to increment/decrement pitch or volume by sampling the SJ-One Board’s on-board push button. When an input is active, the appropriate command gets sent to the MIDI task.

Implementation

MIDI Task Algorithm

1. Sleep and wait for a command.

2. If the play note command is received, then send the MIDI standard message via SPI to the MIDI decoder to play each note in the Note Queue.

3. If the increment/decrement volume command is received, then send the MIDI standard message via SPI to the MIDI decoder to increment/decrement the volume of the MIDI decoder.

4. If the increment/decrement pitch command is received, then offset base note by one range.


IR Key Sampling and Activation Algorithm

1. Using SPI, read 12 ADC channels (6 ADC, 2 channels each) to obtain the values of all 12 IR sensors.

2. Compare each value of the 12 IR sensors against valid margin levels.

3. If a key meets the valid active margin level, the note of the key is sent to the MIDI task Note’s Queue to be played.

4. For keys previously in the active state, if its value meets the valid inactive margin level, then the note of the key is sent to the MIDI task Note’s Queue to be turned off.

5. After all 12 values are checked, if any note had been sent to the MIDI task’s Note Queue, then update the key’s LED based on its new state.

6. Then, after all 12 values are checked AND if any note had been sent to the MIDI task’s Note Queue, send the command Play Note to the MIDI task’s Command Queue.


Control Task User Input Sampling and Activation Algorithm

1. Read the state of the SJ-One Board’s on-board push button.

2. If the increment pitch button is sampled active, then send the increment pitch command to the MIDI task; similarly, if the decrement pitch button is sampled active, then send the decrement pitch command to the MIDI task.

3. If the increment volume button is sampled active, then send the increment volume command to the MIDI task; similarly, if the decrement volume button is sampled active, then send the decrement volume command to the MIDI task.

Testing & Technical Challenges

Testing was done on individual parts and then on combined parts as part of a circuit. Finally, testing was done on the project as a whole. First, testing was done on the IR sensors in order to read values while moving our hands over it and using the SJ-One Board's analog to digital converter. At the same time, testing was done on the VS1033 by sending MIDI messages to it and playing the noise through headphones. Next, the IR sensors were attached to the VS1033 in order to activate noise when motion passes over the sensor. The external analog to digital converters are then tested for reading input from hand motions to all 12 keys. This circuit was then attached to the VS1033 in order to test for notes being played with the keys. Finally, the LED driver was tested separately by sending SPI messages in order to output the connected LEDs. Finally, the LED driver was implemented with the rest of the system such that hand motion over the IR sensors was able to play sounds as well as light LEDs.

LED driver soldering

At first, the LED driver had difficulty implementing. The problem that occurred was that the soldering of the LED driver to the TSSOP to DIP20 adapter may have created a short along the way. After fixing the soldering, the data was able to be sent to the LED driver as expected.

ADC chip select

A problem occurred when implementing the analog to digital convertors. When testing one ADC, the rest of the ADCs' chip selects were left floating. This led to bus contention. The problem was fixed by making all other un-used CS pins from the other ADCs high (not active), while the CS being used was low (active).

Conclusion

Conclude your project here. You can recap your testing and problems. You should address the "so what" part here to indicate what you ultimately learnt from this project. How has this project increased your knowledge?

Project Video

https://youtu.be/DqBue8DKsk0

Project Source Code

References

Acknowledgement

Special acknowledgement to Preetpal Kang for suggesting IR sensors instead of motion sensors.

References Used

Analog to digital converter datasheet Media: CMPE146_F15_ElectricPiano_ADC.pdf

Audio jack data sheet Media:CMPE146_F15_ElectricPiano_AudioJack.pdf

LED data sheet Media:CMPE146_F15_ElectricPiano_LED.pdf

LED driver data sheet Media:CMPE146_F15_ElectricPiano_LEDdriver.pdf

Short IR data sheet Media: CMPE146_F15_ElectricPiano_shortIR.pdf

USB connector data sheet Media:CMPE146_F15_ElectricPiano_USB.pdf

VS1033 data sheet Media:CMPE146_F15_ElectricPiano_LED.pdf

Appendix

You can list the references you used.