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I am trying to program a MSP430 with a simple "FIR filter" program, that looks like the following:

#include "msp430x22x4.h"
#include "legacymsp430.h"

#define FILTER_LENGTH 4
#define TimerA_counter_value 12000                // 12000 counts/s -> 12000 counts ~ 1 Hz

int i;
double x[FILTER_LENGTH+1] = {0,0,0,0,0};
double y = 0;
double b[FILTER_LENGTH+1] = {0.0338,    0.2401,    0.4521,    0.2401,    0.0338};

signed char floor_and_convert(double y);

void setup(void)
{
WDTCTL = WDTPW + WDTHOLD;                       // Stop WDT
BCSCTL1 = CALBC1_8MHZ;                          // Set DCO
DCOCTL = CALDCO_8MHZ;

/* Setup Port 3 */
P3SEL |= BIT4 + BIT5;                           // P3.4,5 = USART0 TXD/RXD
P3DIR |= BIT4;                                  // P3.4 output direction

/* UART */
UCA0CTL1 = UCSSEL_2;                            // SMCLK
UCA0BR0 = 0x41;                                 // 9600 baud from 8Mhz
UCA0BR1 = 0x3;
UCA0MCTL = UCBRS_2;                       
UCA0CTL1 &= ~UCSWRST;                           // **Initialize USCI state machine**
IE2 |= UCA0RXIE;                                // Enable USCI_A0 RX interrupt

/* Setup TimerA */
BCSCTL3 |= LFXT1S_2;                            // LFXT1S_2: Mode 2 for LFXT1 = VLO 
                                                // VLO provides a typical frequency of 12kHz
TACCTL0 = CCIE;                                 // TACCR0 Capture/compare interrupt enable
TACCR0 = TimerA_counter_value;                  // Timer A Capture/Compare 0: -> 25 Hz
TACTL = TASSEL_1;                               // TASSEL_1: Timer A clock source select: 1 - ACLK 

TACTL |= MC_1;                                  // Start Timer_A in up mode  
__enable_interrupt();
}

void main(void)                                   // Beginning of program
{
setup();                                       // Call Function setup (see above)
_BIS_SR(LPM3_bits);                            // Enter LPM0
}


/* USCIA interrupt service routine */
                                                /*#pragma vector=USCIAB0RX_VECTOR;*/
                                                /*__interrupt void USCI0RX_ISR(void)*/
interrupt (USCIAB0RX_VECTOR) USCI0RX_ISR(void)
{  

TACTL |= MC_1;                                  // Start Timer_A in up mode

x[0] =  (double)((signed char)UCA0RXBUF);      // Read received sample and perform type casts
y = 0;
for(i = 0;i <= FILTER_LENGTH;i++)           // Run FIR filter for each received sample
{
    y += b[i]*x[i];
}       
for(i = FILTER_LENGTH-1;i >= 0;i--)         // Roll x array in order to hold old sample inputs
{
    x[i+1] = x[i];
}

while (!(IFG2&UCA0TXIFG));                      // Wait until USART0 TX buffer is ready?
UCA0TXBUF = (signed char) y;
TACTL |= TACLR;                                 // Clear TimerA (prevent interrupt during receive)
}

/* Timer A interrupt service routine */
                                                /*#pragma vector=TIMERA0_VECTOR;*/
                                                /*__interrupt void TimerA_ISR (void)*/
interrupt (TIMERA0_VECTOR) TimerA_ISR(void)
{
for(i = 0;i <= FILTER_LENGTH;i++)           // Clear x array if no data has arrived after 1 sec
{
    x[i] = 0;
}
TACTL &= ~MC_1;                                 // Stops TimerA
}

The program interacts with a MatLab code, that sends 200 doubles to the MSP, for processing in the FIR filter. My problem is, that the MSP is not able to deal with the doubles. I am using the MSPGCC to compile the code. When I send a int to the MSP it will respond be sending a int back again.

share|improve this question
    
Try to simplify the code a lot. If the problem is in the math handling, your example don't need all the interrupt handing code. Also, tell us what you expected to get and what you actually got. –  Lindydancer Mar 27 '12 at 19:54
    
I expected to get a return that matches the values, that the FIR filter in the MATLAB code is producing. I have tried to analyze what came back from the MSP, and I do get some values, but not as many, as it send to the MSP (200). I tried to compile the code in AIR on a windows machine, and when doing that, the code works fine. –  Kaspersoerensen Mar 28 '12 at 15:44

3 Answers 3

Your problem looks like it is in the way that the data is being sent to the MSP.

The communications from MATLAB is, according to your code, a sequence of 4 binary byte values that you then take from the serial port and cast it straight to a double. The value coming in will have a range -128 to +127.

If your source data is any other data size then your program will be broken. If your data source is providing binary "double" data then each value may be 4 or 8 bytes long depending upon its internal data representation. Sending one of these values over the serial port will be interpreted by the MSP as a full set of 4 input samples, resulting in absolute garbage for a set of answers.

The really big question is WHY ON EARTH ARE YOU DOING THIS IN FLOATING POINT - on a 16 bit integer processor that (many versions) have integer multiplier hardware.

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As Ian said, You're taking an 8bit value (UCA0RXBUF is only 8 bits wide anyway) and expecting to get a 32bit or 64 bit value out of it.

In order to get a proper sample you would need to read UCA0RXBUF multiple times and then concatenate each 8 bit value into 32/64 bits which you then would cast to a double.

Like Ian I would also question the wisdom of doing floating point math in a Low power embedded microcontroller. This type of task is much better suited to a DSP.

At least you should use fixed point math, seewikipedia (even in a DSP you would use fixed point arithmetic).

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Hmm. Actually the code is made of my teacher, I'm just trying to make it work on my Mac, and not in AIR :-)

MATLAB code is like this:

function FilterTest(comport)
Fs  =   100;            % Sampling Frequency
Ts  =   1/Fs;           % Sampling Periode
L = 200;                % Number of samples

N = 4;                  % Filter order
Fcut = 5;               % Cut-off frequency
B = fir1(N,Fcut/(Fs/2)) % Filter coefficients in length N+1 vector B

t = [0:L-1]*Ts;         % time array
A_m = 80;               % Amplitude of main component
F_m = 5;                % Frequency of main component
P_m = 80;               % Phase of main component

y_m = A_m*sin(2*pi*F_m*t - P_m*(pi/180));

A_s = 40;               % Amplitude of secondary component
F_s = 40;               % Frequency of secondary component
P_s = 20;               % Phase of secondary component

y_s = A_s*sin(2*pi*F_s*t - P_s*(pi/180));

y = round(y_m + y_s);   % sum of main and secondary components (rounded to integers)

y_filt = round(filter(B,1,y)); % filtered data (rounded to integers)

%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
Serial_port_object = serial(comport);           % create Serial port object
set(Serial_port_object,'InputBufferSize',L)     % set InputBufferSize to length of data
set(Serial_port_object,'OutputBufferSize',L)    % set OutputBufferSize to length of data
fopen(Serial_port_object)                       % open Com Port
fwrite(Serial_port_object,y,'int8');            % send out data
data = fread(Serial_port_object,L,'int8');      % read back data
fclose(Serial_port_object)                      % close Com Port
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%

subplot(2,1,1)
hold off
plot(t,y)
hold on
plot(t,y_filt,'r')
plot(t,y_filt,'ro')
plot(t,data,'k.')
ylabel('Amplitude')
legend('y','y filt (PC)','y filt (PC)','y filt (muP)')

subplot(2,1,2)
hold off
plot(t,data'-y_filt)
hold on
xlabel('time')
ylabel('muP - PC')
figure(1)
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