Interactive Device Design
:)
Dependencies: MbedJSONValue DebounceIn TextLCD USBDevice mbed WebSocketClient cc3000_hostdriver_mbedsocket Adafruit_LEDBackpack_2
main.cpp
- Committer:
- ddrew73
- Date:
- 2014-11-24
- Revision:
- 5:03d75ad40d5e
- Parent:
- 4:5d27966f93e4
- Child:
- 6:d0a1eba7f943
File content as of revision 5:03d75ad40d5e:
#include "mbed.h"
#include <string>
#include "Adafruit_LEDBackpack.h"
#include "Adafruit_GFX.h"
#include "TextLCD.h"
#include "DebounceIn.h"
#include "USBKeyboard.h"
#include "cc3000.h"
#include "Websocket.h"
#include "MbedJSONValue.h"
//LED stuff
I2C i2c(D7,D6);
Adafruit_24bargraph ledbar_left=Adafruit_24bargraph(&i2c);
I2C i2c(D7,D6);
Adafruit_24bargraph ledbar_right=Adafruit_24bargraph(&i2c);
DebounceIn upbutton(D9);
DebounceIn downbutton(D8);
DebounceIn leftbutton( );
DebounceIn rightbutton( );
//Scanner stuff
DebounceIn scanbutton(D10);
DigitalOut A_in(D0);
DigitalOut B_in(D1);
DigitalOut C_in(D2);
DigitalOut A_out(PTC7);
DigitalOut B_out(PTC0);
DigitalOut C_out(PTC3);
AnalogOut dac(PTE30);
AnalogIn adc(PTB0);
//USBKeyboard keyboard;
//LCD stuff
TextLCD lcd(D13,D12,PTA17,PTA16,PTC17,PTC16,TextLCD::LCD20x4);
// cc3000 KL25Z wifi connection
// we need to define connection pins for:
// - IRQ => (pin D3)
// - Enable => (pin D5)
// - SPI CS => (pin D10)
// - SPI MOSI => (pin D11)
// - SPI MISO => (pin D12)
// - SPI CLK => (pin D13)
// plus wifi network SSID, password, security level and smart-configuration flag.
mbed_cc3000::cc3000 wifi(D3, D5, D10, SPI(D11, D12, D13),
"SSID", "PASSWORD", WPA2, false);
Websocket ws("ws://sockets.mbed.org/ws/toastboard/rw");
int main()
{
//Scan init
float test_val = .001;
float row_volt = 0;
int con_mat[24][2] = {};
int a1,b1,c1,a2,b2,c2;
float volt_mat[24][2] = {};
//dac = test_val;
//LED init
int redcount = 0, greencount = 0, rowselect = 0, rowselect_old = 0, moved = 1, colselect = 0;
ledbar_left.begin(0x70);
ledbar_left.clear();
ledbar_left.writeDisplay();
ledbar_right.begin(0x70);
ledbar_right.clear();
ledbar_right.writeDisplay();
//LCD init
lcd.cls();
string programname = "Dan's UI Test";
lcd.printf("%s",programname.c_str());
while(1) {
//Display
if (colselect == 0) {
ledbar_left.clear();
ledbar_right.clear();
ledbar_left.setBar(rowselect,LED_GREEN);
ledbar_left.writeDisplay();
ledbar_right.writeDisplay();
} else
ledbar_left.clear();
ledbar_right.clear();
ledbar_right.setBar(rowselect,LED_GREEN);
ledbar_right.writeDisplay();
ledbar_left.writeDisplay();
//Moving the selected row
if (upbutton.read() == 0) {
rowselect_old = rowselect;
rowselect = rowselect-1;
moved = 1;
wait(0.75);
}
if (downbutton.read() == 0) {
rowselect_old = rowselect;
rowselect = rowselect+1;
moved = 1;
wait(0.75);
}
if (leftbutton.read() == 0) {
colselect = 0;
ledbar_right.clear();
moved =1;
wait(0.75);
}
if (rightbutton.read() == 0) {
colselect = 1;
ledbar_left.clear();
moved =1;
wait(0.75);
}
//Boundary checking
if (rowselect > 23) {
rowselect = 23;
}
if (rowselect < 0) {
rowselect = 0;
}
//Implementing scanning
if (scanbutton.read() == 0) {
for (int x = 0; x < 8; x++) {
for (int y = 0; y < 8; y++) {
// Stupid logic to convert count value to binary...
A_in = x%2;
a1 = x%2;
B_in = (x/2)%2;
b1 = (x/2)%2;
C_in = (x/4)%2;
c1 = (x/4)%2;
A_out = y%2;
int a2 = y%2;
B_out = (y/2)%2;
b2 = (y/2)%2;
C_out = (y/4)%2;
c2 = (y/4)%2;
// Now we do the scan test, results are stored in con_mat
//wait(0.01);
dac = test_val;
float in_val = adc.read();
if ((in_val > .0010) && (in_val < .0025))
con_mat[x][y] = 1;
else
con_mat[x][y] = 0;
//keyboard.printf("%f %f \n",dac.read(),in_val);
//keyboard.printf("%d %d %d\n",a2,b2,c2);
}
}
/*
for (int x=0;x<8;x++) {
for (int y=0;y<8;y++) {
keyboard.printf("%d ",con_mat[x][y]);
}}
*/
//Displaying all connected rows as red light!
ledbar.clear();
for (int i=0; i<8; i++) {
if (con_mat[rowselect][i] == 1) {
ledbar.setBar(i,LED_RED);
}
}
ledbar.writeDisplay();
float vddmeasure = 3.14259;
float vrowmeasure = 1.1234;
lcd.cls();
lcd.locate(0,1);
lcd.printf("Vdd: %1.1f V",vddmeasure);
lcd.locate(0,0);
lcd.printf("Row: %1.1f V",vrowmeasure);
wait(2.5);
ledbar.clear();
ledbar.writeDisplay();
lcd.cls();
string programname = "Dan's UI Test";
lcd.printf("%s",programname.c_str());
}
}
}
/*
///// PUT ALL BELOW IN SCAN BUTTON IF ////////
//Scans rows connected to vdd and ground. Vdd = 2 in con mat, Ground = 3. Rows connected to selected row = 1.
//SET MULTIPLEXER TO READ VDD
vddval = adc.read();
//SET MULTIPLEXER TO READ SELECTED ROW
rowval = adc.read();
ledbar_left.clear();
ledbar_right.clear();
for (int x = 0; x < 2; x++) {
for (int y = 0; y < 24; y++) {
A_in = x%2;
a1 = x%2;
B_in = (x/2)%2;
b1 = (x/2)%2;
C_in = (x/4)%2;
c1 = (x/4)%2;
A_out = y%2;
int a2 = y%2;
B_out = (y/2)%2;
b2 = (y/2)%2;
C_out = (y/4)%2;
c2 = (y/4)%2;
float in_val = adc.read();
volt_mat[x][y] = in_val;
if (in_val == vddval){
con_mat[x][y] = 2;
if (x == 0){
ledbar_left.setBar(y,LED_RED);
}
else {
ledbar_right.setBar(y,LED_RED);
}
}
if (in_val == 0){
con_mat[x][y] = 3;
if (x == 0){
ledbar_left.setBar(y,LED_YELLOW);
}
else {
ledbar_right.setBar(y,LED_YELLOW);
}
}
if (in_val == rowval){
con_mat[x][y] = 1;
if (x == 0){
ledbar_left.setBar(y,LED_GREEN);
}
else {
ledbar_right.setBar(y,LED_GREEN);
}
}
else
con_mat[x][y] = 0;
}
}
moved = 0;
//// PUT ALL ABOVE IN SCAN BUTTON IF /////
if (moved==0) {
ledbar_left.writeDisplay();
ledbar_right.writeDisplay();
lcd.cls();
lcd.locate(0,1);
lcd.printf("Vdd: %1.1f V",vddval);
lcd.locate(0,0);
lcd.printf("Row: %1.1f V",rowval);
}
else {
lcd.cls();
string programname = "Dan's UI Test";
string instructions = "Select a row and scan it";
lcd.locate(0,0);
lcd.printf("%s",programname.c_str());
lcd.locate(0,1);
lcd.printf("%s",instructions.c_str());
}
//Q: Do we need to do the same test for ground or can 0.00 be assumed?
//Q: What is the most efficient way to compare all the "volt_mat" elements?
//Q: Do we need to add a "confidence interval" around the rowval and vdd tests?
*/