Quicksand micro-electronics
This program simulates a dual dice throw by pushing the 2 buttons on the QW dev kit. The results of the throw are shown in binary on the leds, printed in the console window and transmitted via Sigfox.
Fork of
QW-BinaryDices
by 
Quicksand
QW Binary Dices
This program simulates a dual dice throw by pushing the 2 buttons on the QW dev kit. The results of the throw are shown in binary on the leds, printed in the console window and transmitted via Sigfox.
Code explanation
The program starts with the initialisation/declaration of the leds and pushbuttons. Also the necessary function prototypes and serial communications are declared. After that, the program enters an infinite loop and waits till both buttons have been pushed. Once both buttons have been pushed, the result is shown in binary on the leds (LED_3 = LSB), printed in the console window and transmitted via Sigfox. When the Sigfox message is transmitted, the program is ready to throw the dices again.
Sigfox message payload
First there is the "04", this is the Quicksand ID of the example program. This is used by Quicksand to keep track of our example programs. The second value that is transmitted is the number that was thrown by the dices.
More information and other example code can be found on the component page by clicking the link below: https://developer.mbed.org/components/QW-SIGFOX-Development-Kit/
VCNL4010.cpp
- Committer:
- quicksand
- Date:
- 2015-11-05
- Revision:
- 0:6c17d1a79f75
File content as of revision 0:6c17d1a79f75:
/*
Copyright (c) 2012 Vishay GmbH, www.vishay.com
author: DS, version 1.21
Permission is hereby granted, free of charge, to any person obtaining a copy
of this software and associated documentation files (the "Software"), to deal
in the Software without restriction, including without limitation the rights
to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
copies of the Software, and to permit persons to whom the Software is
furnished to do so, subject to the following conditions:
The above copyright notice and this permission notice shall be included in
all copies or substantial portions of the Software.
THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
THE SOFTWARE.
*/
#include "VCNL4010.h"
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0::VCNL40x0(PinName sda, PinName scl, unsigned char addr) : _i2c(sda, scl), _addr(addr) {
// _i2c.frequency(1000000); // set I2C frequency to 1MHz
}
VCNL40x0::~VCNL40x0() {
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetCommandRegister (unsigned char Command) {
_send[0] = REGISTER_COMMAND; // VCNL40x0 Configuration reister
_send[1] = Command;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadCommandRegister (unsigned char *Command) {
_send[0] = REGISTER_COMMAND; // VCNL40x0 Configuration register
_i2c.write(VCNL40x0_ADDRESS,_send, 1); // Write 1 byte on I2C
_i2c.read(VCNL40x0_ADDRESS+1,_receive, 1); // Read 1 byte on I2C
*Command = (unsigned char)(_receive[0]);
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadID (unsigned char *ID) {
_send[0] = REGISTER_ID; // VCNL40x0 product ID revision register
_i2c.write(VCNL40x0_ADDRESS, _send, 1); // Write 1 byte on I2C
_i2c.read(VCNL40x0_ADDRESS+1, _receive, 1); // Read 1 byte on I2C
*ID = (unsigned char)(_receive[0]);
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetCurrent (unsigned char Current) {
_send[0] = REGISTER_PROX_CURRENT; // VCNL40x0 IR LED Current register
_send[1] = Current;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadCurrent (unsigned char *Current) {
_send[0] = REGISTER_PROX_CURRENT; // VCNL40x0 IR LED current register
_i2c.write(VCNL40x0_ADDRESS,_send, 1); // Write 1 byte on I2C
_i2c.read(VCNL40x0_ADDRESS+1,_receive, 1); // Read 1 byte on I2C
*Current = (unsigned char)(_receive[0]);
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetProximityRate (unsigned char ProximityRate) {
_send[0] = REGISTER_PROX_RATE; // VCNL40x0 Proximity rate register
_send[1] = ProximityRate;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetAmbiConfiguration (unsigned char AmbiConfiguration) {
_send[0] = REGISTER_AMBI_PARAMETER; // VCNL40x0 Ambilight configuration
_send[1] = AmbiConfiguration;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetInterruptControl (unsigned char InterruptControl) {
_send[0] = REGISTER_INTERRUPT_CONTROL; // VCNL40x0 Interrupt Control register
_send[1] = InterruptControl;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadInterruptControl (unsigned char *InterruptControl) {
_send[0] = REGISTER_INTERRUPT_CONTROL; // VCNL40x0 Interrupt Control register
_i2c.write(VCNL40x0_ADDRESS,_send, 1); // Write 1 byte on I2C
_i2c.read(VCNL40x0_ADDRESS+1,_receive, 1); // Read 1 byte on I2C
*InterruptControl = (unsigned char)(_receive[0]);
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetInterruptStatus (unsigned char InterruptStatus) {
_send[0] = REGISTER_INTERRUPT_STATUS; // VCNL40x0 Interrupt Status register
_send[1] = InterruptStatus;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetModulatorTimingAdjustment (unsigned char ModulatorTimingAdjustment) {
_send[0] = REGISTER_PROX_TIMING; // VCNL40x0 Modulator Timing Adjustment register
_send[1] = ModulatorTimingAdjustment;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadInterruptStatus (unsigned char *InterruptStatus) {
_send[0] = REGISTER_INTERRUPT_STATUS; // VCNL40x0 Interrupt Status register
_i2c.write(VCNL40x0_ADDRESS,_send, 1); // Write 1 byte on I2C
_i2c.read(VCNL40x0_ADDRESS+1,_receive, 1); // Read 1 byte on I2C
*InterruptStatus = (unsigned char)(_receive[0]);
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadProxiValue (unsigned int *ProxiValue) {
_send[0] = REGISTER_PROX_VALUE; // VCNL40x0 Proximity Value register
_i2c.write(VCNL40x0_ADDRESS, _send, 1); // Write 1 byte on I2C
_i2c.read(VCNL40x0_ADDRESS+1, _receive, 2); // Read 2 bytes on I2C
*ProxiValue = ((unsigned int)_receive[0] << 8 | (unsigned char)_receive[1]);
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadAmbiValue (unsigned int *AmbiValue) {
_send[0] = REGISTER_AMBI_VALUE; // VCNL40x0 Ambient Light Value register
_i2c.write(VCNL40x0_ADDRESS, _send, 1); // Write 1 byte on I2C
_i2c.read(VCNL40x0_ADDRESS+1, _receive, 2); // Read 2 bytes on I2C
*AmbiValue = ((unsigned int)_receive[0] << 8 | (unsigned char)_receive[1]);
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetLowThreshold (unsigned int LowThreshold) {
unsigned char LoByte=0, HiByte=0;
LoByte = (unsigned char)(LowThreshold & 0x00ff);
HiByte = (unsigned char)((LowThreshold & 0xff00)>>8);
_send[0] = REGISTER_INTERRUPT_LOW_THRES; // VCNL40x0 Low Threshold Register, Hi Byte
_send[1] = HiByte;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
_send[0] = REGISTER_INTERRUPT_LOW_THRES+1; // VCNL40x0 Low Threshold Register, Lo Byte
_send[1] = LoByte;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::SetHighThreshold (unsigned int HighThreshold) {
unsigned char LoByte=0, HiByte=0;
LoByte = (unsigned char)(HighThreshold & 0x00ff);
HiByte = (unsigned char)((HighThreshold & 0xff00)>>8);
_send[0] = REGISTER_INTERRUPT_HIGH_THRES; // VCNL40x0 High Threshold Register, Hi Byte
_send[1] = HiByte;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
_send[0] = REGISTER_INTERRUPT_HIGH_THRES+1; // VCNL40x0 High Threshold Register, Lo Byte
_send[1] = LoByte;
_i2c.write(VCNL40x0_ADDRESS,_send, 2); // Write 2 bytes on I2C
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadProxiOnDemand (unsigned int *ProxiValue) {
unsigned char Command=0;
// enable prox value on demand
SetCommandRegister (COMMAND_PROX_ENABLE | COMMAND_PROX_ON_DEMAND);
// wait on prox data ready bit
do {
ReadCommandRegister (&Command); // read command register
} while (!(Command & COMMAND_MASK_PROX_DATA_READY));
ReadProxiValue (ProxiValue); // read prox value
SetCommandRegister (COMMAND_ALL_DISABLE); // stop prox value on demand
return VCNL40x0_ERROR_OK;
}
////////////////////////////////////////////////////////////////////////////////////////////////////////////////
VCNL40x0Error_e VCNL40x0::ReadAmbiOnDemand (unsigned int *AmbiValue) {
unsigned char Command=0;
// enable ambi value on demand
SetCommandRegister (COMMAND_PROX_ENABLE | COMMAND_AMBI_ON_DEMAND);
// wait on ambi data ready bit
do {
ReadCommandRegister (&Command); // read command register
} while (!(Command & COMMAND_MASK_AMBI_DATA_READY));
ReadAmbiValue (AmbiValue); // read ambi value
SetCommandRegister (COMMAND_ALL_DISABLE); // stop ambi value on demand
return VCNL40x0_ERROR_OK;
}