Matrix - Ball Rolling Switch
Contents
1 Introduction
- The Matrix-Ball_Rolling_Switch module is a ball switch. Its electrical characteristics are very similar to a mercury switch's however a mercury switch is easily broken, oxidized, leaking and not environment-friendly. This ball switch prevents all these issues.
- The switch is free to move any angle and if that angle is between 15 degrees and 45 degrees a signal will be generated and used as an input to a Schmitt trigger.
2 Features
- GPIO
- Small
- 2.54 mm spacing pin header
- PCB Dimension(mm):16 x 16
- Pin Description:
Pin | Description |
S | Digital GPIO |
V | Supply Voltage 5V |
G | Ground |
3 Basic Device Operation
Please connect Pin V to a power supply, Pin G grounded and Pin S to a digital output. When you move the switch pushing the internal metal ball to connect the trigger point a high level signal will be generated and output to a Schmitt trigger which reverses this signal to output a low level signal. When you move the switch pushing the internal metal ball away from the trigger point a low level signal will be generated and output to a Schmitt trigger which reverses this signal to output a high level signal.
4 Applications
4.1 Connect to NanoPi M1
Refer to the following connection diagram to connect the module to the NanoPi M1:
Connection Details:
Matrix-Ball_Rolling_Switch | NanoPi M1 |
S | Pin7 |
V | Pin4 |
G | Pin6 |
4.2 Connect to NanoPi 2
Refer to the following connection diagram to connect the module to the NanoPi 2:
Connection Details:
Matrix-Ball_Rolling_Switch | NanoPi 2 |
S | Pin7 |
V | Pin4 |
G | Pin6 |
4.3 Connect to NanoPi M2 / NanoPi 2 Fire
Refer to the following connection diagram to connect the module to the NanoPi M2/ NanoPi 2 Fire.
Connection Details:
Matrix-Ball_Rolling_Switch | NanoPi M2 |
S | Pin7 |
V | Pin4 |
G | Pin6 |
4.4 Connect to NanoPC-T2
Refer to the following connection diagram to connect the module to the NanoPC-T2:
Matrix-Ball_Rolling_Switch_NanoPC-T2
Connection Details:
Matrix-Ball_Rolling_Switch | NanoPC-T2 |
S | Pin15 |
V | Pin29 |
G | Pin30 |
5 Compile & Run Test Program
Boot your ARM board with Debian and copy the matrix code:
$ apt-get update && apt-get install git $ git clone https://github.com/friendlyarm/matrix.git
If your cloning is done successfully a "matrix" directory will be generated.
Compile and install Matrix:
$ cd matrix $ make && make install
Run test program:
$ matrix-gpio_int
Note: this module is not plug and play therefore before running the module please make sure it is connected to an ARM board.
Here is what you should observe:
Waiting event... Device[0] value is 1
When you tilt the module, roll the ball and make it touch the trigger point you will see an event is detected.
6 Code Sample
This Matrix code sample can work with all the ARM boards mentioned in this module's wiki. The name of this code sample is "matrix-gpio_int". Here is its source code:
int main(int argc, char ** argv) { int i, board; int retSize = -1; char value[ARRAY_SIZE(dev)]; if ((board = boardInit()) < 0) printf("Fail to init board\n"); if (argc == 2) { dev[0].pin = atoi(argv[1]); } printf("Using GPIO_PIN(%d)\n", dev[0].pin); system("modprobe "DRIVER_MODULE); signal(SIGINT, intHandler); if (board == BOARD_NANOPI_T2) dev[0].pin = GPIO_PIN(15); if ((devFD =sensorInit(dev, ARRAY_SIZE(dev))) == -1) { printf("Fail to init sensor\n"); return -1; } printf("Waiting event...\n"); if ((retSize = sensorRead(devFD, value, ARRAY_SIZE(dev))) == -1) { printf("Fail to read sensors\n"); } if (retSize > 0) { i = 0; for (i=0; i<retSize; i++) { printf("dev[%d] value: %d\n", i, value[i]); } } sensorDeinit(devFD); system("rmmod "DRIVER_MODULE); return 0; }
For more details about this APIs called in this code sample refer to Matrix API reference manual
7 Resources
- [Schematic](Matrix - Ball Rolling Switch-Schematic.pdf)
8 Update Log
8.1 Feb-24-2016
- Added the driver's source code location in Section 5.2
8.2 June-17-2016
- Re-organized and simplified wiki