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howtos:hardware:arm:interfacing_i2c_devices [2014/03/18 20:43 (UTC)]
louigi600 [Communicating With An I2C Device]
howtos:hardware:arm:interfacing_i2c_devices [2019/07/31 01:39 (UTC)] (current)
rramp [Voltage Level Shifting]
Line 69: Line 69:
 I chose the ITG3200 because it has a temperature sensor inside and I'm hoping I can read that without having to do any calibration,​ just for the sake of keeping the example as simple as possible. According to the chart the temperature register addresses are 1b and 1c so let's go and try and get some data out of there: I chose the ITG3200 because it has a temperature sensor inside and I'm hoping I can read that without having to do any calibration,​ just for the sake of keeping the example as simple as possible. According to the chart the temperature register addresses are 1b and 1c so let's go and try and get some data out of there:
  
-  root@pi:~# i2cdump ​ -r 0x1b-0x1c 1 0x69 b +  root@pi:~# i2cdump  ​-y -r 0x1b-0x1c 1 0x69 b
-  WARNING! This program can confuse your I2C bus, cause data loss and worse! +
-  I will probe file /dev/i2c-1, address 0x69, mode byte +
-  Probe range limited to 0x1b-0x1c. +
-  Continue? [Y/n] y+
        ​0 ​ 1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef        ​0 ​ 1  2  3  4  5  6  7  8  9  a  b  c  d  e  f    0123456789abcdef
   10:                                  c0 90                        ??      10:                                  c0 90                        ??   
   root@pi:~#   root@pi:~#
  
-So we got c090 as our temperature reading. According to the datasheet this value is a 2's compliment of the temperature. So let's try and figure out what that would be: c090 written in binary is 1100000010010000, ​the most significant bit is 1 so the result ​should ​be -16240  +The above example dumps registers 1b and 1c from the ITG3200 ​the same result ​can be achieved with i2cget:
-   +
-    -a_{N-1} 2^{N-1} + \sum_{i=0}^{N-2} a_i 2^i +
  
-But I was unable to find in the datasheet what units this reading is in but they did mention that there was an average offset of 13200. I did a little google search and found this formula:+  root@pi:~# i2cget -y  1 0x69  0x1b b 
 +  0xc0 
 +  root@pi:~# i2cget -y  1 0x69  0x1c b 
 +  0x90 
 +  root@pi:​~#​ 
 + 
 +So we got c090 as our temperature reading. According to the datasheet this value is a 2's compliment of the temperature. So let's try and figure out what that would be: c090 written in binary is 1100000010010000,​ the most significant bit is 1 so the result should be  
 +  16528 - 32768 = -16240 ​  
 +I was unable to find in the datasheet what units this reading is in but they did mention that there was an average offset of 13200. I did a little google search and found this formula:
  
   35 + ((raw value + 13200) / 280))   35 + ((raw value + 13200) / 280))
   35 + ((13200 - 16240)/280) = 24.14   35 + ((13200 - 16240)/280) = 24.14
  
-Considering that my current ambient temperature is about 20 Celcius I guess that for uncalibrated data that's OK+Considering that my current ambient temperature is about 20 Celcius I guess that for uncalibrated data that's OK
 + 
 +If you want a script that does the maths for you and just reads out the ITG3200 sensor data in a human readable format here's an example: 
 + 
 +  #​!/​bin/​bash 
 +  BUS=1 
 +  ID=0x69 
 +  ATH=0x1b 
 +  ATL=0x1c 
 +  ARXH=0x1d 
 +  ARXL=0x1e 
 +  ARYH=0x1f 
 +  ARYL=0x20 
 +  ARZH=0x21 
 +  ARZL=0x22 
 +   
 +  #need upper case hex stripped of prefix "​0x"​ or bc will not like the input 
 +  for VAR in TH TL RXH RXL RYH RYL RZH RZL 
 +  do 
 +    CMD="​$VAR=\$(i2cget -y $BUS $ID \$A$VAR ​ b |sed -e "​s/​^0x//"​ |tr "​a-z"​ "​A-Z"​)"​ 
 +    eval $CMD 
 +    eval "echo $VAR = \$$VAR"​ 
 +  done 
 +   
 +  echo "Temp register: $(echo "​ibase=16;​ $TH$TL"​ | bc -l) 0x$TH$TL ($(echo "​ibase=16;​ obase=2; $TH$TL"​ | bc -l))"​ 
 +   
 +  echo -n "Temp in Celcius: " 
 +  #this takes hex input and evaluates the followin formula in hexadecimal 
 +  #temp= 35 + ((raw + 13200) / 280))"​ 
 +  #where raw is the input reading un 2's compliment  
 +  #(to uncompliment the input I take away 0x10000 if input is larger then 0x8000) 
 +  echo "​ibase=16;​ input=$TH$TL;​ if ( input >= 8000 ) { raw=input - 10000;} else { raw=input;​};​ 23 + ((raw + 3390)/​118);"​ |bc -l 
 +   
 +  echo "X Axis Rotation Register: $(echo "​ibase=16;​ $RXH$RXL"​ | bc -l) 0x$RXH$RXL ($(echo "​ibase=16;​ obase=2; $RXH$RXL"​ | bc -l))"​ 
 +  echo -n "X Axis Angula velocity degree/sec: " 
 +  echo "​ibase=16;​ input=$RXH$RXL;​ if ( input >= 8000 ) { raw= input - 10000;} else { raw=input;​};​ raw / E.177" |bc -l 
 +   
 +  echo "Y Axis Rotation Register: $(echo "​ibase=16;​ $RYH$RYL"​ | bc -l) 0x$RYH$RYL ($(echo "​ibase=16;​ obase=2; $RYH$RYL"​ | bc -l))"​ 
 +  echo -n "Y Axis Angula velocity degree/sec: " 
 +  echo "​ibase=16;​ input=$RYH$RYL;​ if ( input >= 8000 ) { raw= input - 10000;} else { raw=input;​};​ raw / E.177" |bc -l 
 +   
 +  echo "Z Axis Rotation Register: $(echo "​ibase=16;​ $RZH$RZL"​ | bc -l) 0x$RZH$RZL ($(echo "​ibase=16;​ obase=2; $RZH$RZL"​ | bc -l))"​ 
 +  echo -n "Z Axis Angula velocity degree/sec: " 
 +  echo "​ibase=16;​ input=$RZH$RZL;​ if ( input >= 8000 ) { raw= input - 10000;} else { raw=input;​};​ raw / E.177" |bc -l 
 + 
 +The above script just does one simple dump of the register data and converts the values into human readable format, it does nothing with regards to calibration and averaging out vibrations. More consistent gyroscopic readings would be achieved if an average over 10 consecutive data samples was made thus averaging out most of the ambient vibrations.  
 + 
 +A bash script is really not the most suitable way to read data from I2C devices, a faster means of managing the data from the devices is really mandatory in order to do calibration,​ data averaging and what more to make the information consistent and useful for further calculations. I found the Linux kernel i2c documentation a usefull reference (<kernel source tree>/​Documentation/​i2c/​dev-interface);​ it's not the only way that data can be read but it's a good starting point. 
 + 
 +I hate showing my poor C programming capabilities but here's some code that uses i2c-dev to read stuff from the ITG3200 and takes an average over 10 readings: 
 + 
 +  #include <​sys/​ioctl.h>​ 
 +  #include <​errno.h>​ 
 +  #include <​string.h>​ 
 +  #include <​stdio.h>​ 
 +  #include <​stdlib.h>​ 
 +  #include <​unistd.h>​ 
 +  #include <​linux/​i2c-dev.h>​ 
 +  #include <​fcntl.h>​ 
 +  #include <​errno.h>​ 
 +   
 +  #define I2C_DEVICE "/​dev/​i2c-1"​ 
 +   
 +  /​*ITG3200*/​ 
 +  #define ITG3200_ADDR 0x69 
 +  #define ITG3200_SELF 0x0 
 +  #define ITG3200_INT 0x1a 
 +  #define ITG3200_TH 0x1b /*2 bytes Hight byte and Low byte*/ 
 +  #define ITG3200_TL 0x1c 
 +  #define ITG3200_XRH 0x1d /*2 byte Hight byte and Low byte*/ 
 +  #define ITG3200_XRL 0x1e 
 +  #define ITG3200_YRH 0x1f /*2 byte Hight byte and Low byte*/ 
 +  #define ITG3200_YRL 0x20 
 +  #define ITG3200_ZRH 0x21 /*2 byte Hight byte and Low byte*/ 
 +  #define ITG3200_ZRL 0x22 /*2 byte Hight byte and Low byte*/ 
 +  #define ITG3200_TEMP_RAW_OFFSET 13200 
 +  #define ITG3200_TEMP_RAW_SENSITIVITY 280 
 +  #define ITG3200_TEMP_OFFSET 35 
 +  #define ITG3200_ROT_RAW_SENSITIVITY 14.375 
 +   
 +  int twosc2int(int twoscomplimentdata) 
 +  { int retval; 
 +    if( twoscomplimentdata > 32768 ) retval = twoscomplimentdata - 65536; 
 +    else retval = twoscomplimentdata;​ 
 +    return retval; 
 +  } 
 +   
 +  float ITG3200_rot_conv(int rawdata) 
 +  { float retval; 
 +    int raw; 
 +   
 +    raw=twosc2int(rawdata);​ 
 +    retval = (float)raw / (float)ITG3200_ROT_RAW_SENSITIVITY;​ 
 +    return retval; 
 +  } 
 +   
 +  float ITG3200_temp_conv(int rawdata) 
 +  { float retval; 
 +    int raw; 
 +   
 +    raw=twosc2int(rawdata);​ 
 +    retval = (float)ITG3200_TEMP_OFFSET + (((float)raw + ITG3200_TEMP_RAW_OFFSET) / ITG3200_TEMP_RAW_SENSITIVITY);​ 
 +    return retval; 
 +  } 
 +   
 +  void ITG3200_read (int file, int *raw, int *reg_array,​int size) 
 +  { __s32 res; 
 +    int i,j,k; 
 +   
 +    for(i=0;​i<​size;​i++) 
 +    { k=0; 
 +      for (j=0;​j<​2;​j++) 
 +      { 
 +        if( (res = i2c_smbus_read_byte_data(file,​*(reg_array + i + j)) )< 0 ) 
 +        { printf("​Failed to read from the i2c bus.\n"​);​ 
 +          exit(1); 
 +        } 
 +        if (j == 0) k=(int)res << 8; 
 +        else 
 +        { k += (int)res; 
 +          *(raw + (i/2))=k; 
 +        } 
 +      } 
 +      i++; 
 +    } 
 +  } 
 +   
 +  main () 
 +  { int file; 
 +    int i,j,k; 
 +    float data[4]={0};​ 
 +   
 +    int ITG3200_REGS[8]={ITG3200_TH,​ITG3200_TL,​ITG3200_XRH,​ITG3200_XRL,​ 
 +      ITG3200_YRH,​ ITG3200_YRL,​ITG3200_ZRH,​ITG3200_ZRL};​ 
 +    int ITG3200_RAW_DATA[4];​ 
 +    float ITG3200_DATA[4];​ 
 +   
 +    if ((file = open(I2C_DEVICE,​ O_RDWR)) < 0) 
 +    { perror("​Failed to open the i2c bus"​);​ 
 +      exit(1); 
 +    } 
 +   
 +    if (ioctl(file,​ I2C_SLAVE, ITG3200_ADDR) < 0) 
 +    { printf("​Failed to acquire bus access and/or talk to slave.\n"​);​ 
 +      exit(1); 
 +    } 
 +   
 +  /*Take an avarage over 10 consecuitve readings on the ITG3200*/ 
 +    for (i=0;​i<​10;​i++) 
 +    { ITG3200_read(file,&​ITG3200_RAW_DATA[0],&​ITG3200_REGS[0],​sizeof(ITG3200_REGS)/​sizeof(ITG3200_REGS[0]));​ 
 +   
 +      data[0] += ITG3200_temp_conv(ITG3200_RAW_DATA[0]);​ 
 +      data[1] += ITG3200_rot_conv(ITG3200_RAW_DATA[1]);​ 
 +      data[2] += ITG3200_rot_conv(ITG3200_RAW_DATA[2]);​ 
 +      data[3] += ITG3200_rot_conv(ITG3200_RAW_DATA[3]);​ 
 +    } 
 +    for(i=0;​i<​4;​i++) data[i] /= 10;  
 +   
 +    printf("​Temp. : %2.2f \n",​data[0]);​ 
 +    printf("​Rot. X : %2.2f \n",​data[1]);​ 
 +    printf("​Rot. Y : %2.2f \n",​data[2]);​ 
 +    printf("​Rot. Z : %2.2f \n",​data[3]);​ 
 +   
 +    close(file);​ 
 +  } 
 + 
 ====== Voltage Level Shifting ====== ====== Voltage Level Shifting ======
 You may end up with heterogeneous voltage level devices and if you have many devices the correct way to work around this problem is by using bidirectional I2C voltage level shifters like the [[ http://​www.ti.com/​lit/​ds/​symlink/​pca9306.pdf |PCA9306]], but if you only have a few devices all grouped up in a neat PCB like the 10DOF IMU unit you might want to give a simpler system a try. You may end up with heterogeneous voltage level devices and if you have many devices the correct way to work around this problem is by using bidirectional I2C voltage level shifters like the [[ http://​www.ti.com/​lit/​ds/​symlink/​pca9306.pdf |PCA9306]], but if you only have a few devices all grouped up in a neat PCB like the 10DOF IMU unit you might want to give a simpler system a try.
-This is how I connected my 5v IMU pcb to a 3.3v I2C bus on my RaspberryPI:​ I took as educated guess that 4.4v (5v with a 4148 diode in series) would still be a tolerable power supply voltage for the whole IMU pcb, this would most likely allow all the I2C devices on the IMU pcb to recognize a minimum of 3.08v (4.4 * 0.7) as the lowest reliable logic level 1 tension allowing it to inter-operate with the PI's 3.3v logig levels. I was not able to find if the PI has internal pullups on the I2C bus or if they have to be externally placed so in doubt I put in 10k pullups between the 4.4v power line and the 2 data lines. I was the able to correctly detect the sensors on the IMU pcb.   +This is how I connected my 5v IMU pcb to a 3.3v I2C bus on my RaspberryPI:​ I took as educated guess that 4.4v (5v with a 4148 diode in series) would still be a tolerable power supply voltage for the whole IMU pcb, this would most likely allow all the I2C devices on the IMU pcb to recognize a minimum of 3.08v (4.4 * 0.7) as the lowest reliable logic level 1 tension allowing it to inter-operate with the PI's 3.3v logic levels. I was not able to find if the PI has internal pullups on the I2C bus or if they have to be externally placed so in doubt I put in 10k pullups between the 4.4v power line and the 2 data lines. I was the able to correctly detect the sensors on the IMU pcb.   
  
 ====== Sources ====== ====== Sources ======

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