lemming lemming
Adjusts the great pinscape controller to work with a cheap linear potentiometer instead of the expensive CCD array
Fork of
Pinscape_Controller
by 
Mike R
Revision 1:d913e0afb2ac, committed 2014-07-16
- Comitter:
- mjr
- Date:
- Wed Jul 16 23:33:12 2014 +0000
- Parent:
- 0:5acbbe3f4cf4
- Child:
- 2:c174f9ee414a
- Commit message:
- Before removing time/frequency limit on reading the plunger sensor
Changed in this revision
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/FreescaleIAP.cpp Wed Jul 16 23:33:12 2014 +0000
@@ -0,0 +1,190 @@
+#include "FreescaleIAP.h"
+
+//#define IAPDEBUG
+
+enum FCMD {
+ Read1s = 0x01,
+ ProgramCheck = 0x02,
+ ReadResource = 0x03,
+ ProgramLongword = 0x06,
+ EraseSector = 0x09,
+ Read1sBlock = 0x40,
+ ReadOnce = 0x41,
+ ProgramOnce = 0x43,
+ EraseAll = 0x44,
+ VerifyBackdoor = 0x45
+ };
+
+inline void run_command(void);
+bool check_boundary(int address, unsigned int length);
+bool check_align(int address);
+IAPCode verify_erased(int address, unsigned int length);
+IAPCode check_error(void);
+IAPCode program_word(int address, char *data);IAPCode program_word(int address, char *data);
+
+IAPCode erase_sector(int address) {
+ #ifdef IAPDEBUG
+ printf("IAP: Erasing at %x\r\n", address);
+ #endif
+ if (check_align(address))
+ return AlignError;
+
+ //Setup command
+ FTFA->FCCOB0 = EraseSector;
+ FTFA->FCCOB1 = (address >> 16) & 0xFF;
+ FTFA->FCCOB2 = (address >> 8) & 0xFF;
+ FTFA->FCCOB3 = address & 0xFF;
+
+ run_command();
+
+ return check_error();
+}
+
+IAPCode program_flash(int address, char *data, unsigned int length) {
+ #ifdef IAPDEBUG
+ printf("IAP: Programming flash at %x with length %d\r\n", address, length);
+ #endif
+ if (check_align(address))
+ return AlignError;
+
+ IAPCode eraseCheck = verify_erased(address, length);
+ if (eraseCheck != Success)
+ return eraseCheck;
+
+ IAPCode progResult;
+ for (int i = 0; i < length; i+=4) {
+ progResult = program_word(address + i, data + i);
+ if (progResult != Success)
+ return progResult;
+ }
+
+ return Success;
+}
+
+uint32_t flash_size(void) {
+ uint32_t retval = (SIM->FCFG2 & 0x7F000000u) >> (24-13);
+ if (SIM->FCFG2 & (1<<23)) //Possible second flash bank
+ retval += (SIM->FCFG2 & 0x007F0000u) >> (16-13);
+ return retval;
+}
+
+IAPCode program_word(int address, char *data) {
+ #ifdef IAPDEBUG
+ printf("IAP: Programming word at %x, %d - %d - %d - %d\r\n", address, data[0], data[1], data[2], data[3]);
+ #endif
+ if (check_align(address))
+ return AlignError;
+
+ //Setup command
+ FTFA->FCCOB0 = ProgramLongword;
+ FTFA->FCCOB1 = (address >> 16) & 0xFF;
+ FTFA->FCCOB2 = (address >> 8) & 0xFF;
+ FTFA->FCCOB3 = address & 0xFF;
+ FTFA->FCCOB4 = data[3];
+ FTFA->FCCOB5 = data[2];
+ FTFA->FCCOB6 = data[1];
+ FTFA->FCCOB7 = data[0];
+
+ run_command();
+
+ return check_error();
+}
+
+/* Clear possible flags which are set, run command, wait until done */
+inline void run_command(void) {
+ //Clear possible old errors, start command, wait until done
+ FTFA->FSTAT = FTFA_FSTAT_FPVIOL_MASK | FTFA_FSTAT_ACCERR_MASK | FTFA_FSTAT_RDCOLERR_MASK;
+ FTFA->FSTAT = FTFA_FSTAT_CCIF_MASK;
+ while (!(FTFA->FSTAT & FTFA_FSTAT_CCIF_MASK));
+}
+
+
+
+/* Check if no flash boundary is violated
+ Returns true on violation */
+bool check_boundary(int address, unsigned int length) {
+ int temp = (address+length - 1) / SECTOR_SIZE;
+ address /= SECTOR_SIZE;
+ bool retval = (address != temp);
+ #ifdef IAPDEBUG
+ if (retval)
+ printf("IAP: Boundary violation\r\n");
+ #endif
+ return retval;
+}
+
+/* Check if address is correctly aligned
+ Returns true on violation */
+bool check_align(int address) {
+ bool retval = address & 0x03;
+ #ifdef IAPDEBUG
+ if (retval)
+ printf("IAP: Alignment violation\r\n");
+ #endif
+ return retval;
+}
+
+/* Check if an area of flash memory is erased
+ Returns error code or Success (in case of fully erased) */
+IAPCode verify_erased(int address, unsigned int length) {
+ #ifdef IAPDEBUG
+ printf("IAP: Verify erased at %x with length %d\r\n", address, length);
+ #endif
+
+ if (check_align(address))
+ return AlignError;
+
+ //Setup command
+ FTFA->FCCOB0 = Read1s;
+ FTFA->FCCOB1 = (address >> 16) & 0xFF;
+ FTFA->FCCOB2 = (address >> 8) & 0xFF;
+ FTFA->FCCOB3 = address & 0xFF;
+ FTFA->FCCOB4 = (length >> 10) & 0xFF;
+ FTFA->FCCOB5 = (length >> 2) & 0xFF;
+ FTFA->FCCOB6 = 0;
+
+ run_command();
+
+ IAPCode retval = check_error();
+ if (retval == RuntimeError) {
+ #ifdef IAPDEBUG
+ printf("IAP: Flash was not erased\r\n");
+ #endif
+ return EraseError;
+ }
+ return retval;
+
+}
+
+/* Check if an error occured
+ Returns error code or Success*/
+IAPCode check_error(void) {
+ if (FTFA->FSTAT & FTFA_FSTAT_FPVIOL_MASK) {
+ #ifdef IAPDEBUG
+ printf("IAP: Protection violation\r\n");
+ #endif
+ return ProtectionError;
+ }
+ if (FTFA->FSTAT & FTFA_FSTAT_ACCERR_MASK) {
+ #ifdef IAPDEBUG
+ printf("IAP: Flash access error\r\n");
+ #endif
+ return AccessError;
+ }
+ if (FTFA->FSTAT & FTFA_FSTAT_RDCOLERR_MASK) {
+ #ifdef IAPDEBUG
+ printf("IAP: Collision error\r\n");
+ #endif
+ return CollisionError;
+ }
+ if (FTFA->FSTAT & FTFA_FSTAT_MGSTAT0_MASK) {
+ #ifdef IAPDEBUG
+ printf("IAP: Runtime error\r\n");
+ #endif
+ return RuntimeError;
+ }
+ #ifdef IAPDEBUG
+ printf("IAP: No error reported\r\n");
+ #endif
+ return Success;
+}
\ No newline at end of file
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/FreescaleIAP.h Wed Jul 16 23:33:12 2014 +0000
@@ -0,0 +1,87 @@
+/*
+ * Freescale FTFA Flash Memory programmer
+ *
+ * Sample usage:
+
+#include "mbed.h"
+#include "FreescaleIAP.h"
+
+int main() {
+ int address = flash_size() - SECTOR_SIZE; //Write in last sector
+
+ int *data = (int*)address;
+ printf("Starting\r\n");
+ erase_sector(address);
+ int numbers[10] = {0, 1, 10, 100, 1000, 10000, 1000000, 10000000, 100000000, 1000000000};
+ program_flash(address, (char*)&numbers, 40); //10 integers of 4 bytes each: 40 bytes length
+ printf("Resulting flash: \r\n");
+ for (int i = 0; i<10; i++)
+ printf("%d\r\n", data[i]);
+
+ printf("Done\r\n\n");
+
+
+ while (true) {
+ }
+}
+
+*/
+
+#ifndef FREESCALEIAP_H
+#define FREESCALEIAP_H
+
+#include "mbed.h"
+
+#ifdef TARGET_KLXX
+#define SECTOR_SIZE 1024
+#elif TARGET_K20D5M
+#define SECTOR_SIZE 2048
+#elif TARGET_K64F
+#define SECTOR_SIZE 4096
+#else
+#define SECTOR_SIZE 1024
+#endif
+
+enum IAPCode {
+ BoundaryError = -99, //Commands may not span several sectors
+ AlignError, //Data must be aligned on longword (two LSBs zero)
+ ProtectionError, //Flash sector is protected
+ AccessError, //Something went wrong
+ CollisionError, //During writing something tried to flash which was written to
+ LengthError, //The length must be multiples of 4
+ RuntimeError,
+ EraseError, //The flash was not erased before writing to it
+ Success = 0
+ };
+
+/** Erase a flash sector
+ *
+ * The size erased depends on the used device
+ *
+ * @param address address in the sector which needs to be erased
+ * @param return Success if no errors were encountered, otherwise one of the error states
+ */
+IAPCode erase_sector(int address);
+
+/** Program flash
+ *
+ * Before programming the used area needs to be erased. The erase state is checked
+ * before programming, and will return an error if not erased.
+ *
+ * @param address starting address where the data needs to be programmed (must be longword alligned: two LSBs must be zero)
+ * @param data pointer to array with the data to program
+ * @param length number of bytes to program (must be a multiple of 4)
+ * @param return Success if no errors were encountered, otherwise one of the error states
+ */
+IAPCode program_flash(int address, char *data, unsigned int length);
+
+/**
+ * Returns size of flash memory
+ *
+ * This is the first address which is not flash
+ *
+ * @param return length of flash memory in bytes
+ */
+uint32_t flash_size(void);
+
+#endif
--- a/MMA8451Q.lib Fri Jul 11 03:26:11 2014 +0000 +++ /dev/null Thu Jan 01 00:00:00 1970 +0000 @@ -1,1 +0,0 @@ -http://mbed.org/users/emilmont/code/MMA8451Q/#c4d879a39775
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/MMA8451Q/MMA8451Q.cpp Wed Jul 16 23:33:12 2014 +0000
@@ -0,0 +1,176 @@
+/* Copyright (c) 2010-2011 mbed.org, MIT License
+*
+* 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 "MMA8451Q.h"
+
+#define REG_WHO_AM_I 0x0D
+#define REG_CTRL_REG_1 0x2A
+#define REG_CTRL_REG_2 0x2B
+#define REG_CTRL_REG_3 0x2c
+#define REG_CTRL_REG_4 0x2D
+#define REG_CTRL_REG_5 0x2E
+#define REG_OFF_X 0x2F
+#define REG_OFF_Y 0x30
+#define REG_OFF_Z 0x31
+#define XYZ_DATA_CFG_REG 0x0E
+#define REG_OUT_X_MSB 0x01
+#define REG_OUT_Y_MSB 0x03
+#define REG_OUT_Z_MSB 0x05
+
+#define UINT14_MAX 16383
+
+#define CTL_ACTIVE 0x01
+#define FS_MASK 0x03
+#define FS_2G 0x00
+#define FS_4G 0x01
+#define FS_8G 0x02
+
+#define HPF_OUT_MASK 0x10
+
+#define MODS1_MASK 0x02
+#define MODS0_MASK 0x01
+#define SMODS_MASK 0x18
+#define MODS_MASK 0x03
+
+#define DR_MASK 0x38
+#define DR_800_HZ 0x00
+#define DR_400_HZ 0x08
+#define DR_200_HZ 0x10
+#define DR_100_HZ 0x18
+#define DR_50_HZ 0x20
+#define DR_12_HZ 0x28
+#define DR_6_HZ 0x30
+#define DR_1_HZ 0x38
+
+
+MMA8451Q::MMA8451Q(PinName sda, PinName scl, int addr) : m_i2c(sda, scl), m_addr(addr)
+{
+ // go to standby mode
+ standby();
+
+ // read the curent config register
+ uint8_t d1[1];
+ readRegs(XYZ_DATA_CFG_REG, d1, 1);
+
+ // set 2g mode
+ uint8_t d2[2] = { XYZ_DATA_CFG_REG, (d1[0] & ~FS_MASK) | FS_2G };
+ writeRegs(d2, 2);
+
+ // read the ctl2 register
+ uint8_t d3[1];
+ readRegs(REG_CTRL_REG_2, d3, 1);
+
+ // set the high resolution mode
+ uint8_t d4[2] = {REG_CTRL_REG_2, (d3[0] & ~MODS_MASK) | MODS1_MASK};
+ writeRegs(d4, 2);
+
+ // set 50 Hz mode
+ uint8_t d5[1];
+ readRegs(REG_CTRL_REG_1, d5, 1);
+
+ uint8_t d6[2] = {REG_CTRL_REG_1, (d5[0] & ~DR_MASK) | DR_100_HZ};
+ writeRegs(d6, 2);
+
+ // enter active mode
+ active();
+}
+
+MMA8451Q::~MMA8451Q() { }
+
+void MMA8451Q::standby()
+{
+ // read the current control register
+ uint8_t d1[1];
+ readRegs(REG_CTRL_REG_1, d1, 1);
+
+ // write it back witht he Active bit cleared
+ uint8_t d2[2] = { REG_CTRL_REG_1, d1[0] & ~CTL_ACTIVE };
+ writeRegs(d2, 2);
+}
+
+void MMA8451Q::active()
+{
+ // read the current control register
+ uint8_t d1[1];
+ readRegs(REG_CTRL_REG_1, d1, 1);
+
+ // write it back out with the Active bit set
+ uint8_t d2[2] = { REG_CTRL_REG_1, d1[0] | CTL_ACTIVE };
+ writeRegs(d2, 2);
+}
+
+uint8_t MMA8451Q::getWhoAmI() {
+ uint8_t who_am_i = 0;
+ readRegs(REG_WHO_AM_I, &who_am_i, 1);
+ return who_am_i;
+}
+
+float MMA8451Q::getAccX() {
+ return (float(getAccAxis(REG_OUT_X_MSB))/4096.0);
+}
+
+void MMA8451Q::getAccXY(float &x, float &y)
+{
+ // read the X and Y output registers
+ uint8_t res[4];
+ readRegs(REG_OUT_X_MSB, res, 4);
+
+ // translate the x value
+ uint16_t acc = (res[0] << 8) | (res[1]);
+ x = int16_t(acc)/(4*4096.0);
+
+ // translate the y value
+ acc = (res[2] << 9) | (res[3]);
+ y = int16_t(acc)/(4*4096.0);
+}
+
+float MMA8451Q::getAccY() {
+ return (float(getAccAxis(REG_OUT_Y_MSB))/4096.0);
+}
+
+float MMA8451Q::getAccZ() {
+ return (float(getAccAxis(REG_OUT_Z_MSB))/4096.0);
+}
+
+void MMA8451Q::getAccAllAxis(float * res) {
+ res[0] = getAccX();
+ res[1] = getAccY();
+ res[2] = getAccZ();
+}
+
+int16_t MMA8451Q::getAccAxis(uint8_t addr) {
+ int16_t acc;
+ uint8_t res[2];
+ readRegs(addr, res, 2);
+
+ acc = (res[0] << 6) | (res[1] >> 2);
+ if (acc > UINT14_MAX/2)
+ acc -= UINT14_MAX;
+
+ return acc;
+}
+
+void MMA8451Q::readRegs(int addr, uint8_t * data, int len) {
+ char t[1] = {addr};
+ m_i2c.write(m_addr, t, 1, true);
+ m_i2c.read(m_addr, (char *)data, len);
+}
+
+void MMA8451Q::writeRegs(uint8_t * data, int len) {
+ m_i2c.write(m_addr, (char *)data, len);
+}
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/MMA8451Q/MMA8451Q.h Wed Jul 16 23:33:12 2014 +0000
@@ -0,0 +1,125 @@
+/* Copyright (c) 2010-2011 mbed.org, MIT License
+*
+* 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.
+*/
+
+#ifndef MMA8451Q_H
+#define MMA8451Q_H
+
+#include "mbed.h"
+
+/**
+* MMA8451Q accelerometer example
+*
+* @code
+* #include "mbed.h"
+* #include "MMA8451Q.h"
+*
+* #define MMA8451_I2C_ADDRESS (0x1d<<1)
+*
+* int main(void) {
+*
+* MMA8451Q acc(P_E25, P_E24, MMA8451_I2C_ADDRESS);
+* PwmOut rled(LED_RED);
+* PwmOut gled(LED_GREEN);
+* PwmOut bled(LED_BLUE);
+*
+* while (true) {
+* rled = 1.0 - abs(acc.getAccX());
+* gled = 1.0 - abs(acc.getAccY());
+* bled = 1.0 - abs(acc.getAccZ());
+* wait(0.1);
+* }
+* }
+* @endcode
+*/
+class MMA8451Q
+{
+public:
+ /**
+ * MMA8451Q constructor
+ *
+ * @param sda SDA pin
+ * @param sdl SCL pin
+ * @param addr addr of the I2C peripheral
+ */
+ MMA8451Q(PinName sda, PinName scl, int addr);
+
+ /**
+ * MMA8451Q destructor
+ */
+ ~MMA8451Q();
+
+ /**
+ * Enter standby mode
+ */
+ void standby();
+
+ /**
+ * Enter active mode
+ */
+ void active();
+
+ /**
+ * Get the value of the WHO_AM_I register
+ *
+ * @returns WHO_AM_I value
+ */
+ uint8_t getWhoAmI();
+
+ /**
+ * Get X axis acceleration
+ *
+ * @returns X axis acceleration
+ */
+ float getAccX();
+
+ /**
+ * Get Y axis acceleration
+ *
+ * @returns Y axis acceleration
+ */
+ float getAccY();
+
+ /**
+ * Read an X,Y pair
+ */
+ void getAccXY(float &x, float &y);
+
+ /**
+ * Get Z axis acceleration
+ *
+ * @returns Z axis acceleration
+ */
+ float getAccZ();
+
+ /**
+ * Get XYZ axis acceleration
+ *
+ * @param res array where acceleration data will be stored
+ */
+ void getAccAllAxis(float * res);
+
+private:
+ I2C m_i2c;
+ int m_addr;
+ void readRegs(int addr, uint8_t * data, int len);
+ void writeRegs(uint8_t * data, int len);
+ int16_t getAccAxis(uint8_t addr);
+
+};
+
+#endif
--- a/USBJoystick.cpp Fri Jul 11 03:26:11 2014 +0000
+++ b/USBJoystick.cpp Wed Jul 16 23:33:12 2014 +0000
@@ -99,9 +99,9 @@
LOGICAL_MINIMUM(1), 0x81, // each value ranges -127...
LOGICAL_MAXIMUM(1), 0x7f, // ...to 127
REPORT_SIZE(1), 0x08, // 8 bits per report
- REPORT_COUNT(1), 0x03, // 3 reports
+ REPORT_COUNT(1), 0x03, // 2 reports
INPUT(1), 0x02, // Data, Variable, Absolute
-
+
REPORT_COUNT(1), 0x08, // input report count (LEDWiz messages)
0x09, 0x01, // usage
0x91, 0x01, // Output (array)
--- a/main.cpp Fri Jul 11 03:26:11 2014 +0000
+++ b/main.cpp Wed Jul 16 23:33:12 2014 +0000
@@ -1,31 +1,34 @@
#include "mbed.h"
#include "USBJoystick.h"
#include "MMA8451Q.h"
-#include "tls1410r.h"
+#include "tsl1410r.h"
+#include "FreescaleIAP.h"
+// on-board RGB LED elements - we use these for diagnostics
PwmOut led1(LED1), led2(LED2), led3(LED3);
-DigitalOut out1(PTE29);
-
+// calibration button - switch input and LED output
+DigitalIn calBtn(PTE29);
+DigitalOut calBtnLed(PTE23);
static int pbaIdx = 0;
// on/off state for each LedWiz output
-static uint8_t ledOn[32];
+static uint8_t wizOn[32];
// profile (brightness/blink) state for each LedWiz output
-static uint8_t ledVal[32] = {
+static uint8_t wizVal[32] = {
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0,
0, 0, 0, 0, 0, 0, 0, 0
};
-static double ledState(int idx)
+static float wizState(int idx)
{
- if (ledOn[idx]) {
+ if (wizOn[idx]) {
// on - map profile brightness state to PWM level
- uint8_t val = ledVal[idx];
+ uint8_t val = wizVal[idx];
if (val >= 1 && val <= 48)
return 1.0 - val/48.0;
else if (val >= 129 && val <= 132)
@@ -39,27 +42,75 @@
}
}
-static void updateLeds()
+static void updateWizOuts()
+{
+ led1 = wizState(0);
+ led2 = wizState(1);
+ led3 = wizState(2);
+}
+
+struct AccPrv
{
- led1 = ledState(0);
- led2 = ledState(1);
- led3 = ledState(2);
-}
+ AccPrv() : x(0), y(0) { }
+ float x;
+ float y;
+
+ double dist(AccPrv &b)
+ {
+ float dx = x - b.x, dy = y - b.y;
+ return sqrt(dx*dx + dy*dy);
+ }
+};
int main(void)
{
+ // turn off our on-board indicator LED
led1 = 1;
led2 = 1;
led3 = 1;
- Timer timer;
+
+ // plunger calibration data
+ const int npix = 320;
+ int plungerMin = 0, plungerMax = npix;
+
+ // plunger calibration button debounce timer
+ Timer calBtnTimer;
+ calBtnTimer.start();
+ int calBtnDownTime = 0;
+ int calBtnLit = false;
+
+ // Calibration button state:
+ // 0 = not pushed
+ // 1 = pushed, not yet debounced
+ // 2 = pushed, debounced, waiting for hold time
+ // 3 = pushed, hold time completed - in calibration mode
+ int calBtnState = 0;
+
+ // set up a timer for our heartbeat indicator
+ Timer hbTimer;
+ hbTimer.start();
+ int t0Hb = hbTimer.read_ms();
+ int hb = 0;
+
+ // set a timer for accelerometer auto-centering
+ Timer acTimer;
+ acTimer.start();
+ int t0ac = acTimer.read_ms();
+
+ // set up a timer for reading the plunger sensor
+ Timer ccdTimer;
+ ccdTimer.start();
+ int t0ccd = ccdTimer.read_ms();
+
+#if 0
+ // DEBUG
+ Timer ccdDbgTimer;
+ ccdDbgTimer.start();
+ int t0ccdDbg = ccdDbgTimer.read_ms();
+#endif
- // set up a timer for spacing USB reports
- timer.start();
- float t0 = timer.read_ms();
- float tout1 = timer.read_ms();
-
- // Create the joystick USB client. Show a read LED while connecting, and
- // change to green when connected.
+ // Create the joystick USB client. Light the on-board indicator LED
+ // red while connecting, and change to green after we connect.
led1 = 0.75;
USBJoystick js(0xFAFA, 0x00F7, 0x0001);
led1 = 1;
@@ -68,13 +119,23 @@
// create the accelerometer object
const int MMA8451_I2C_ADDRESS = (0x1d<<1);
MMA8451Q accel(PTE25, PTE24, MMA8451_I2C_ADDRESS);
- printf("MMA8451 ID: %d\r\n", accel.getWhoAmI());
// create the CCD array object
- TLS1410R ccd(PTE20, PTE21, PTB0);
+ TSL1410R ccd(PTE20, PTE21, PTB0);
+
+ // recent accelerometer readings, for auto centering
+ int iAccPrv = 0, nAccPrv = 0;
+ const int maxAccPrv = 5;
+ AccPrv accPrv[maxAccPrv];
- // process sensor reports and LedWiz requests forever
- int x = 0, y = 127, z = 0;
+ // last accelerometer report, in mouse coordinates
+ int x = 127, y = 127, z = 0;
+
+ // raw accelerator centerpoint, on the unit interval (-1.0 .. +1.0)
+ float xCenter = 0.0, yCenter = 0.0;
+
+ // we're all set up - now just loop, processing sensor reports and
+ // host requests
for (;;)
{
// Look for an incoming report. Continue processing input as
@@ -85,7 +146,8 @@
while (js.readNB(&report) && report.length == 8)
{
uint8_t *data = report.data;
- if (data[0] == 64) {
+ if (data[0] == 64)
+ {
// LWZ-SBA - first four bytes are bit-packed on/off flags
// for the outputs; 5th byte is the pulse speed (0-7)
//printf("LWZ-SBA %02x %02x %02x %02x ; %02x\r\n",
@@ -98,16 +160,17 @@
bit = 1;
++ri;
}
- ledOn[i] = ((data[ri] & bit) != 0);
+ wizOn[i] = ((data[ri] & bit) != 0);
}
- // update the physical LED state
- updateLeds();
+ // update the physical outputs
+ updateWizOuts();
// reset the PBA counter
pbaIdx = 0;
}
- else {
+ else
+ {
// LWZ-PBA - full state dump; each byte is one output
// in the current bank. pbaIdx keeps track of the bank;
// this is incremented implicitly by each PBA message.
@@ -116,73 +179,242 @@
// update all output profile settings
for (int i = 0 ; i < 8 ; ++i)
- ledVal[pbaIdx + i] = data[i];
+ wizVal[pbaIdx + i] = data[i];
// update the physical LED state if this is the last bank
if (pbaIdx == 24)
- updateLeds();
+ updateWizOuts();
// advance to the next bank
pbaIdx = (pbaIdx + 8) & 31;
}
}
-
-#if 1
- // check the accelerometer
+
+ // check for plunger calibration
+ if (!calBtn)
{
- // read the accelerometer
- float xa = accel.getAccX();
- float ya = accel.getAccY();
-
- // figure the new joystick position
- int xnew = (int)(127 * xa);
- int ynew = (int)(127 * ya);
-
- // send an update if the position has changed
- if (xnew != x || ynew != y)
+ // check the state
+ switch (calBtnState)
{
- x = xnew;
- y = ynew;
-
- // send the status report
- js.update(x, y, z, 0);
+ case 0:
+ // button not yet pushed - start debouncing
+ calBtnTimer.reset();
+ calBtnDownTime = calBtnTimer.read_ms();
+ calBtnState = 1;
+ break;
+
+ case 1:
+ // pushed, not yet debounced - if the debounce time has
+ // passed, start the hold period
+ if (calBtnTimer.read_ms() - calBtnDownTime > 50)
+ calBtnState = 2;
+ break;
+
+ case 2:
+ // in the hold period - if the button has been held down
+ // for the entire hold period, move to calibration mode
+ if (calBtnTimer.read_ms() - calBtnDownTime > 2050)
+ {
+ // enter calibration mode
+ calBtnState = 3;
+
+ // reset the calibration limits
+ plungerMax = 0;
+ plungerMin = npix;
+ }
+ break;
}
}
-#else
- // Send a joystick report if it's been long enough since the
- // last report
- if (timer.read_ms() - t0 > 250)
+ else
+ {
+ // Button released. If we're not already in calibration mode,
+ // reset the button state. Once calibration mode starts, it sticks
+ // until the calibration time elapses.
+ if (calBtnState != 3)
+ calBtnState = 0;
+ else if (calBtnTimer.read_ms() - calBtnDownTime > 32500)
+ calBtnState = 0;
+ }
+
+ // light/flash the calibration button light, if applicable
+ int newCalBtnLit = calBtnLit;
+ switch (calBtnState)
{
- // send the current joystick status report
- js.update(x, y, z, 0);
-
- // update our internal joystick position record
- x += dx;
- y += dy;
- z += dz;
- if (x > xmax || x < xmin) {
- dx = -dx;
- x += 2*dx;
+ case 2:
+ // in the hold period - flash the light
+ newCalBtnLit = (((calBtnTimer.read_ms() - calBtnDownTime)/250) & 1);
+ break;
+
+ case 3:
+ // calibration mode - show steady on
+ newCalBtnLit = true;
+ break;
+
+ default:
+ // not calibrating/holding - show steady off
+ newCalBtnLit = false;
+ break;
+ }
+ if (calBtnLit != newCalBtnLit)
+ {
+ calBtnLit = newCalBtnLit;
+ calBtnLed = (calBtnLit ? 1 : 0);
+ }
+
+ // read the plunger sensor
+ int znew = z;
+ /* if (ccdTimer.read_ms() - t0ccd > 33) */
+ {
+ // read the sensor at reduced resolution
+ uint16_t pix[npix];
+ ccd.read(pix, npix, 0);
+
+#if 0
+ // debug - send samples every 5 seconds
+ if (ccdDbgTimer.read_ms() - t0ccdDbg > 5000)
+ {
+ for (int i = 0 ; i < npix ; ++i)
+ printf("%x ", pix[i]);
+ printf("\r\n\r\n");
+
+ ccdDbgTimer.reset();
+ t0ccdDbg = ccdDbgTimer.read_ms();
}
- if (y > ymax || y < ymin) {
- dy = -dy;
- y += 2*dy;
- }
- if (z > zmax || z < zmin) {
- dz = -dz;
- z += 2*dz;
- }
+#endif
+
+ // check which end is the brighter - this is the "tip" end
+ // of the plunger
+ long avg1 = (long(pix[0]) + long(pix[1]) + long(pix[2]) + long(pix[3]) + long(pix[4]))/5;
+ long avg2 = (long(pix[npix-1]) + long(pix[npix-2]) + long(pix[npix-3]) + long(pix[npix-4]) + long(pix[npix-5]))/5;
+
+ // figure the midpoint in the brightness
+ long midpt = (avg1 + avg2)/2 * 3;
+
+ // Work from the bright end to the dark end. VP interprets the
+ // Z axis value as the amount the plunger is pulled: the minimum
+ // is the rest position, the maximum is fully pulled. So we
+ // essentially want to report how much of the sensor is lit,
+ // since this increases as the plunger is pulled back.
+ int si = 1, di = 1;
+ if (avg1 < avg2)
+ si = npix - 1, di = -1;
- // note the time of the last report
- t0 = timer.read_ms();
- }
-#endif
+ // scan for the midpoint
+ for (int n = 1, i = si ; n < npix - 1 ; ++n, i += di)
+ {
+ // if we've crossed the midpoint, report this position
+ if (long(pix[i-1]) + long(pix[i]) + long(pix[i+1]) < midpt)
+ {
+ // note the new position
+ int pos = abs(i - si);
+
+ // Calibrate, or apply calibration, depending on the mode.
+ // In either case, normalize to a 0-127 range. VP appears to
+ // ignore negative Z axis values.
+ if (calBtnState == 3)
+ {
+ // calibrating - note if we're expanding the calibration envelope
+ if (pos < plungerMin)
+ plungerMin = pos;
+ if (pos > plungerMax)
+ plungerMax = pos;
+
+ // normalize to the full physical range while calibrating
+ znew = int(float(pos)/npix * 127);
+ }
+ else
+ {
+ // running normally - normalize to the calibration range
+ if (pos < plungerMin)
+ pos = plungerMin;
+ if (pos > plungerMax)
+ pos = plungerMax;
+ znew = int(float(pos - plungerMin)/(plungerMax - plungerMin + 1) * 127);
+ }
+
+ // done
+ break;
+ }
+ }
+
+ // reset the timer
+ ccdTimer.reset();
+ t0ccd = ccdTimer.read_ms();
+ }
+
+ // read the accelerometer
+ float xa, ya;
+ accel.getAccXY(xa, ya);
+
+ // check for auto-centering every so often
+ if (acTimer.read_ms() - t0ac > 1000)
+ {
+ // add the sample to the history list
+ accPrv[iAccPrv].x = xa;
+ accPrv[iAccPrv].y = ya;
+
+ // store the slot
+ iAccPrv += 1;
+ iAccPrv %= maxAccPrv;
+ nAccPrv += 1;
+
+ // If we have a full complement, check for stability. The
+ // raw accelerometer input is in the rnage -4096 to 4096, but
+ // the class cover normalizes to a unit interval (-1.0 .. +1.0).
+ const float accTol = .005;
+ if (nAccPrv >= maxAccPrv
+ && accPrv[0].dist(accPrv[1]) < accTol
+ && accPrv[0].dist(accPrv[2]) < accTol
+ && accPrv[0].dist(accPrv[3]) < accTol
+ && accPrv[0].dist(accPrv[4]) < accTol)
+ {
+ // figure the new center
+ xCenter = (accPrv[0].x + accPrv[1].x + accPrv[2].x + accPrv[3].x + accPrv[4].x)/5.0;
+ yCenter = (accPrv[0].y + accPrv[1].y + accPrv[2].y + accPrv[3].y + accPrv[4].y)/5.0;
+ }
+
+ // reset the auto-center timer
+ acTimer.reset();
+ t0ac = acTimer.read_ms();
+ }
+
+ // adjust for our auto centering
+ xa -= xCenter;
+ ya -= yCenter;
+
+ // confine to the unit interval
+ if (xa < -1.0) xa = -1.0;
+ if (xa > 1.0) xa = 1.0;
+ if (ya < -1.0) ya = -1.0;
+ if (ya > 1.0) ya = 1.0;
- // pulse E29
- if (timer.read_ms() - tout1 > 2000)
+ // figure the new mouse report data
+ int xnew = (int)(127 * xa);
+ int ynew = (int)(127 * ya);
+
+ // send an update if the position has changed
+ // if (xnew != x || ynew != y || znew != z)
{
- out1 = !out1;
- tout1 = timer.read_ms();
+ x = xnew;
+ y = ynew;
+ z = znew;
+
+ // Send the status report. Note that the X axis needs to be
+ // reversed, becasue the native accelerometer reports seem to
+ // assume that the card is component side down.
+ js.update(x, -y, z, 0);
}
- }
+
+ // show a heartbeat flash in blue every so often
+ if (hbTimer.read_ms() - t0Hb > 1000)
+ {
+ // invert the blue LED state
+ hb = !hb;
+ led3 = (hb ? .5 : 1);
+
+ // reset the heartbeat timer
+ hbTimer.reset();
+ t0Hb = hbTimer.read_ms();
+ }
+ }
}
--- a/tls1410r.cpp Fri Jul 11 03:26:11 2014 +0000
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,74 +0,0 @@
-#include "mbed.h"
-#include "tls1410r.h"
-
-TLS1410R::TLS1410R(PinName siPort, PinName clockPort, PinName aoPort)
- : si(siPort), clock(clockPort), ao(aoPort)
-{
- // clear out power-on noise by clocking through all pixels twice
- clear();
- clear();
-}
-
-void TLS1410R::clear()
-{
- // clock in an SI pulse
- si = 1;
- clock = 1;
- clock = 0;
- si = 0;
-
- // clock out all pixels
- for (int i = 0 ; i < nPix+1 ; ++i) {
- clock = 1;
- clock = 0;
- }
-}
-
-void TLS1410R::read(uint16_t *pix, int n, int integrate_us)
-{
- // Start an integration cycle - pulse SI, then clock all pixels. The
- // CCD will integrate light starting 18 clocks after the SI pulse, and
- // continues integrating until the next SI pulse, which cannot occur
- // until all pixels have been clocked.
- si = 1;
- clock = 1;
- clock = 0;
- si = 0;
- for (int i = 0 ; i < nPix+1 ; ++i) {
- clock = 1;
- clock = 0;
- }
-
- // delay by the specified additional integration time
- wait_us(integrate_us);
-
- // end the current integration cycle and hold the integrated values
- si = 1;
- clock = 1;
- clock = 0;
- si = 0;
-
- // figure how many pixels to skip on each read
- int skip = nPix/n - 1;
-
- // read the pixels
- for (int src = 0, dst = 0 ; src < nPix ; ++src)
- {
- // read this pixel
- pix[dst++] = ao;
-
- // clock in the next pixel
- clock = 1;
- clock = 0;
-
- // clock skipped pixels
- for (int i = 0 ; i < skip ; ++i) {
- clock = 1;
- clock = 0;
- }
- }
-
- // clock out one extra pixel to make sure the device is ready for another go
- clock = 1;
- clock = 0;
-}
--- a/tls1410r.h Fri Jul 11 03:26:11 2014 +0000
+++ /dev/null Thu Jan 01 00:00:00 1970 +0000
@@ -1,41 +0,0 @@
-/*
- * TLS1410R interface class.
- *
- * This provides a high-level interface for the Taos TLS1410R linear CCD array sensor.
- */
-
- #include "mbed.h"
-
- #ifndef TLS1410R_H
- #define TLS1410R_H
-
-class TLS1410R
-{
-public:
- // set up with the two DigitalOut ports (SI and clock), and the
- // analog in port for reading the currently selected pixel value
- TLS1410R(PinName siPort, PinName clockPort, PinName aoPort);
-
- // Integrate light and read the pixels. Fills in pix[] with the pixel values,
- // scaled 0-0xffff. n is the number of pixels to read; if this is less than
- // the total number of pixels npix, we'll read every mth pixel, where m = npix/n.
- // E.g., if you want 640 pixels out of 1280 on the sensor, we'll read every
- // other pixel. If you want 320, we'll read every fourth pixel.
- // Before reading, we'll pause for integrate_us additional microseconds during
- // the integration phase; use 0 for no additional integration time.
- void read(uint16_t *pix, int n, int integrate_us);
-
- // clock through all pixels to clear the array
- void clear();
-
- // number of pixels in the array
- static const int nPix = 1280;
-
-
-private:
- DigitalOut si;
- DigitalOut clock;
- AnalogIn ao;
-};
-
-#endif /* TLS1410R_H */
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/tsl1410r.h Wed Jul 16 23:33:12 2014 +0000
@@ -0,0 +1,41 @@
+/*
+ * TSL1410R interface class.
+ *
+ * This provides a high-level interface for the Taos TSL1410R linear CCD array sensor.
+ */
+
+ #include "mbed.h"
+
+ #ifndef TSL1410R_H
+ #define TSL1410R_H
+
+class TSL1410R
+{
+public:
+ // set up with the two DigitalOut ports (SI and clock), and the
+ // analog in port for reading the currently selected pixel value
+ TSL1410R(PinName siPort, PinName clockPort, PinName aoPort);
+
+ // Integrate light and read the pixels. Fills in pix[] with the pixel values,
+ // scaled 0-0xffff. n is the number of pixels to read; if this is less than
+ // the total number of pixels npix, we'll read every mth pixel, where m = npix/n.
+ // E.g., if you want 640 pixels out of 1280 on the sensor, we'll read every
+ // other pixel. If you want 320, we'll read every fourth pixel.
+ // Before reading, we'll pause for integrate_us additional microseconds during
+ // the integration phase; use 0 for no additional integration time.
+ void read(uint16_t *pix, int n, int integrate_us);
+
+ // clock through all pixels to clear the array
+ void clear();
+
+ // number of pixels in the array
+ static const int nPix = 1280;
+
+
+private:
+ DigitalOut si;
+ DigitalOut clock;
+ AnalogIn ao;
+};
+
+#endif /* TSL1410R_H */
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/tsl410r.cpp Wed Jul 16 23:33:12 2014 +0000
@@ -0,0 +1,74 @@
+#include "mbed.h"
+#include "tsl1410r.h"
+
+TSL1410R::TSL1410R(PinName siPort, PinName clockPort, PinName aoPort)
+ : si(siPort), clock(clockPort), ao(aoPort)
+{
+ // clear out power-on noise by clocking through all pixels twice
+ clear();
+ clear();
+}
+
+void TSL1410R::clear()
+{
+ // clock in an SI pulse
+ si = 1;
+ clock = 1;
+ clock = 0;
+ si = 0;
+
+ // clock out all pixels
+ for (int i = 0 ; i < nPix+1 ; ++i) {
+ clock = 1;
+ clock = 0;
+ }
+}
+
+void TSL1410R::read(uint16_t *pix, int n, int integrate_us)
+{
+ // Start an integration cycle - pulse SI, then clock all pixels. The
+ // CCD will integrate light starting 18 clocks after the SI pulse, and
+ // continues integrating until the next SI pulse, which cannot occur
+ // until all pixels have been clocked.
+ si = 1;
+ clock = 1;
+ clock = 0;
+ si = 0;
+ for (int i = 0 ; i < nPix+1 ; ++i) {
+ clock = 1;
+ clock = 0;
+ }
+
+ // delay by the specified additional integration time
+ wait_us(integrate_us);
+
+ // end the current integration cycle and hold the integrated values
+ si = 1;
+ clock = 1;
+ clock = 0;
+ si = 0;
+
+ // figure how many pixels to skip on each read
+ int skip = nPix/n - 1;
+
+ // read the pixels
+ for (int src = 0, dst = 0 ; src < nPix ; ++src)
+ {
+ // read this pixel
+ pix[dst++] = ao.read_u16();
+
+ // clock in the next pixel
+ clock = 1;
+ clock = 0;
+
+ // clock skipped pixels
+ for (int i = 0 ; i < skip ; ++i, ++src) {
+ clock = 1;
+ clock = 0;
+ }
+ }
+
+ // clock out one extra pixel to make sure the device is ready for another go
+ clock = 1;
+ clock = 0;
+}