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Finite Impulse Response (FIR) Filters

Functions

void arm_fir_f32 (const arm_fir_instance_f32 *S, const float32_t *pSrc, float32_t *pDst, uint32_t blockSize)
 Processing function for floating-point FIR filter. More...
 
void arm_fir_fast_q15 (const arm_fir_instance_q15 *S, const q15_t *pSrc, q15_t *pDst, uint32_t blockSize)
 Processing function for the Q15 FIR filter (fast version). More...
 
IAR_ONLY_LOW_OPTIMIZATION_ENTER
void 
arm_fir_fast_q31 (const arm_fir_instance_q31 *S, const q31_t *pSrc, q31_t *pDst, uint32_t blockSize)
 Processing function for the Q31 FIR filter (fast version). More...
 
void arm_fir_init_f32 (arm_fir_instance_f32 *S, uint16_t numTaps, const float32_t *pCoeffs, float32_t *pState, uint32_t blockSize)
 Initialization function for the floating-point FIR filter. More...
 
arm_status arm_fir_init_q15 (arm_fir_instance_q15 *S, uint16_t numTaps, const q15_t *pCoeffs, q15_t *pState, uint32_t blockSize)
 Initialization function for the Q15 FIR filter. More...
 
void arm_fir_init_q31 (arm_fir_instance_q31 *S, uint16_t numTaps, const q31_t *pCoeffs, q31_t *pState, uint32_t blockSize)
 Initialization function for the Q31 FIR filter. More...
 
void arm_fir_init_q7 (arm_fir_instance_q7 *S, uint16_t numTaps, const q7_t *pCoeffs, q7_t *pState, uint32_t blockSize)
 Initialization function for the Q7 FIR filter. More...
 
void arm_fir_q15 (const arm_fir_instance_q15 *S, const q15_t *pSrc, q15_t *pDst, uint32_t blockSize)
 Processing function for the Q15 FIR filter. More...
 
void arm_fir_q31 (const arm_fir_instance_q31 *S, const q31_t *pSrc, q31_t *pDst, uint32_t blockSize)
 Processing function for Q31 FIR filter. More...
 
void arm_fir_q7 (const arm_fir_instance_q7 *S, const q7_t *pSrc, q7_t *pDst, uint32_t blockSize)
 Processing function for Q7 FIR filter. More...
 

Description

This set of functions implements Finite Impulse Response (FIR) filters for Q7, Q15, Q31, and floating-point data types. Fast versions of Q15 and Q31 are also provided. The functions operate on blocks of input and output data and each call to the function processes blockSize samples through the filter. pSrc and pDst points to input and output arrays containing blockSize values.

Algorithm
The FIR filter algorithm is based upon a sequence of multiply-accumulate (MAC) operations. Each filter coefficient b[n] is multiplied by a state variable which equals a previous input sample x[n].
    y[n] = b[0] * x[n] + b[1] * x[n-1] + b[2] * x[n-2] + ...+ b[numTaps-1] * x[n-numTaps+1]
FIR.GIF
Finite Impulse Response filter
pCoeffs points to a coefficient array of size numTaps. Coefficients are stored in time reversed order.
    {b[numTaps-1], b[numTaps-2], b[N-2], ..., b[1], b[0]}
pState points to a state array of size numTaps + blockSize - 1. Samples in the state buffer are stored in the following order.
    {x[n-numTaps+1], x[n-numTaps], x[n-numTaps-1], x[n-numTaps-2]....x[0], x[1], ..., x[blockSize-1]}
Note that the length of the state buffer exceeds the length of the coefficient array by blockSize-1. The increased state buffer length allows circular addressing, which is traditionally used in the FIR filters, to be avoided and yields a significant speed improvement. The state variables are updated after each block of data is processed; the coefficients are untouched.
Instance Structure
The coefficients and state variables for a filter are stored together in an instance data structure. A separate instance structure must be defined for each filter. Coefficient arrays may be shared among several instances while state variable arrays cannot be shared. There are separate instance structure declarations for each of the 4 supported data types.
Initialization Functions
There is also an associated initialization function for each data type. The initialization function performs the following operations:
  • Sets the values of the internal structure fields.
  • Zeros out the values in the state buffer. To do this manually without calling the init function, assign the follow subfields of the instance structure: numTaps, pCoeffs, pState. Also set all of the values in pState to zero.
Use of the initialization function is optional. However, if the initialization function is used, then the instance structure cannot be placed into a const data section. To place an instance structure into a const data section, the instance structure must be manually initialized. Set the values in the state buffer to zeros before static initialization. The code below statically initializes each of the 4 different data type filter instance structures
    arm_fir_instance_f32 S = {numTaps, pState, pCoeffs};
    arm_fir_instance_q31 S = {numTaps, pState, pCoeffs};
    arm_fir_instance_q15 S = {numTaps, pState, pCoeffs};
    arm_fir_instance_q7 S =  {numTaps, pState, pCoeffs};
where numTaps is the number of filter coefficients in the filter; pState is the address of the state buffer; pCoeffs is the address of the coefficient buffer.
Fixed-Point Behavior
Care must be taken when using the fixed-point versions of the FIR filter functions. In particular, the overflow and saturation behavior of the accumulator used in each function must be considered. Refer to the function specific documentation below for usage guidelines.

Function Documentation

void arm_fir_f32 ( const arm_fir_instance_f32 S,
const float32_t pSrc,
float32_t pDst,
uint32_t  blockSize 
)

Processing function for the floating-point FIR filter.

Parameters
[in]Spoints to an instance of the floating-point FIR filter structure
[in]pSrcpoints to the block of input data
[out]pDstpoints to the block of output data
[in]blockSizenumber of samples to process
Returns
none
void arm_fir_fast_q15 ( const arm_fir_instance_q15 S,
const q15_t pSrc,
q15_t pDst,
uint32_t  blockSize 
)

Processing function for the fast Q15 FIR filter (fast version).

Parameters
[in]Spoints to an instance of the Q15 FIR filter structure
[in]pSrcpoints to the block of input data
[out]pDstpoints to the block of output data
[in]blockSizenumber of samples to process
Returns
none
Scaling and Overflow Behavior
This fast version uses a 32-bit accumulator with 2.30 format. The accumulator maintains full precision of the intermediate multiplication results but provides only a single guard bit. Thus, if the accumulator result overflows it wraps around and distorts the result. In order to avoid overflows completely the input signal must be scaled down by log2(numTaps) bits. The 2.30 accumulator is then truncated to 2.15 format and saturated to yield the 1.15 result.
Remarks
Refer to arm_fir_q15() for a slower implementation of this function which uses 64-bit accumulation to avoid wrap around distortion. Both the slow and the fast versions use the same instance structure. Use function arm_fir_init_q15() to initialize the filter structure.
IAR_ONLY_LOW_OPTIMIZATION_ENTER void arm_fir_fast_q31 ( const arm_fir_instance_q31 S,
const q31_t pSrc,
q31_t pDst,
uint32_t  blockSize 
)

Processing function for the fast Q31 FIR filter (fast version).

Parameters
[in]Spoints to an instance of the Q31 structure
[in]pSrcpoints to the block of input data
[out]pDstpoints to the block of output data
[in]blockSizenumber of samples to process
Returns
none
Scaling and Overflow Behavior
This function is optimized for speed at the expense of fixed-point precision and overflow protection. The result of each 1.31 x 1.31 multiplication is truncated to 2.30 format. These intermediate results are added to a 2.30 accumulator. Finally, the accumulator is saturated and converted to a 1.31 result. The fast version has the same overflow behavior as the standard version and provides less precision since it discards the low 32 bits of each multiplication result. In order to avoid overflows completely the input signal must be scaled down by log2(numTaps) bits.
Remarks
Refer to arm_fir_q31() for a slower implementation of this function which uses a 64-bit accumulator to provide higher precision. Both the slow and the fast versions use the same instance structure. Use function arm_fir_init_q31() to initialize the filter structure.
void arm_fir_init_f32 ( arm_fir_instance_f32 S,
uint16_t  numTaps,
const float32_t pCoeffs,
float32_t pState,
uint32_t  blockSize 
)
Parameters
[in,out]Spoints to an instance of the floating-point FIR filter structure
[in]numTapsnumber of filter coefficients in the filter
[in]pCoeffspoints to the filter coefficients buffer
[in]pStatepoints to the state buffer
[in]blockSizenumber of samples processed per call
Returns
none
Details
pCoeffs points to the array of filter coefficients stored in time reversed order:
    {b[numTaps-1], b[numTaps-2], b[N-2], ..., b[1], b[0]}
pState points to the array of state variables. pState is of length numTaps+blockSize-1 samples, where blockSize is the number of input samples processed by each call to arm_fir_f32().
arm_status arm_fir_init_q15 ( arm_fir_instance_q15 S,
uint16_t  numTaps,
const q15_t pCoeffs,
q15_t pState,
uint32_t  blockSize 
)
Parameters
[in,out]Spoints to an instance of the Q15 FIR filter structure.
[in]numTapsnumber of filter coefficients in the filter. Must be even and greater than or equal to 4.
[in]pCoeffspoints to the filter coefficients buffer.
[in]pStatepoints to the state buffer.
[in]blockSizenumber of samples processed per call.
Returns
execution status
Details
pCoeffs points to the array of filter coefficients stored in time reversed order:
    {b[numTaps-1], b[numTaps-2], b[N-2], ..., b[1], b[0]}
Note that numTaps must be even and greater than or equal to 4. To implement an odd length filter simply increase numTaps by 1 and set the last coefficient to zero. For example, to implement a filter with numTaps=3 and coefficients
    {0.3, -0.8, 0.3}
set numTaps=4 and use the coefficients:
    {0.3, -0.8, 0.3, 0}.
Similarly, to implement a two point filter
    {0.3, -0.3}
set numTaps=4 and use the coefficients:
    {0.3, -0.3, 0, 0}.
pState points to the array of state variables. pState is of length numTaps+blockSize, when running on Cortex-M4 and Cortex-M3 and is of length numTaps+blockSize-1, when running on Cortex-M0 where blockSize is the number of input samples processed by each call to arm_fir_q15().
void arm_fir_init_q31 ( arm_fir_instance_q31 S,
uint16_t  numTaps,
const q31_t pCoeffs,
q31_t pState,
uint32_t  blockSize 
)
Parameters
[in,out]Spoints to an instance of the Q31 FIR filter structure
[in]numTapsnumber of filter coefficients in the filter
[in]pCoeffspoints to the filter coefficients buffer
[in]pStatepoints to the state buffer
[in]blockSizenumber of samples processed
Returns
none
Details
pCoeffs points to the array of filter coefficients stored in time reversed order:
    {b[numTaps-1], b[numTaps-2], b[N-2], ..., b[1], b[0]}
pState points to the array of state variables. pState is of length numTaps+blockSize-1 samples, where blockSize is the number of input samples processed by each call to arm_fir_q31().
void arm_fir_init_q7 ( arm_fir_instance_q7 S,
uint16_t  numTaps,
const q7_t pCoeffs,
q7_t pState,
uint32_t  blockSize 
)
Parameters
[in,out]Spoints to an instance of the Q7 FIR filter structure
[in]numTapsnumber of filter coefficients in the filter
[in]pCoeffspoints to the filter coefficients buffer
[in]pStatepoints to the state buffer
[in]blockSizenumber of samples processed
Returns
none
Details
pCoeffs points to the array of filter coefficients stored in time reversed order:
    {b[numTaps-1], b[numTaps-2], b[N-2], ..., b[1], b[0]}
pState points to the array of state variables. pState is of length numTaps+blockSize-1 samples, where blockSize is the number of input samples processed by each call to arm_fir_q7().
void arm_fir_q15 ( const arm_fir_instance_q15 S,
const q15_t pSrc,
q15_t pDst,
uint32_t  blockSize 
)
Parameters
[in]Spoints to an instance of the Q15 FIR filter structure
[in]pSrcpoints to the block of input data
[out]pDstpoints to the block of output data
[in]blockSizenumber of samples to process
Returns
none
Scaling and Overflow Behavior
The function is implemented using a 64-bit internal accumulator. Both coefficients and state variables are represented in 1.15 format and multiplications yield a 2.30 result. The 2.30 intermediate results are accumulated in a 64-bit accumulator in 34.30 format. There is no risk of internal overflow with this approach and the full precision of intermediate multiplications is preserved. After all additions have been performed, the accumulator is truncated to 34.15 format by discarding low 15 bits. Lastly, the accumulator is saturated to yield a result in 1.15 format.
Remarks
Refer to arm_fir_fast_q15() for a faster but less precise implementation of this function.
void arm_fir_q31 ( const arm_fir_instance_q31 S,
const q31_t pSrc,
q31_t pDst,
uint32_t  blockSize 
)

Processing function for the Q31 FIR filter.

Parameters
[in]Spoints to an instance of the Q31 FIR filter structure
[in]pSrcpoints to the block of input data
[out]pDstpoints to the block of output data
[in]blockSizenumber of samples to process
Returns
none
Scaling and Overflow Behavior
The function is implemented using an internal 64-bit accumulator. The accumulator has a 2.62 format and maintains full precision of the intermediate multiplication results but provides only a single guard bit. Thus, if the accumulator result overflows it wraps around rather than clip. In order to avoid overflows completely the input signal must be scaled down by log2(numTaps) bits. After all multiply-accumulates are performed, the 2.62 accumulator is right shifted by 31 bits and saturated to 1.31 format to yield the final result.
Remarks
Refer to arm_fir_fast_q31() for a faster but less precise implementation of this filter.
void arm_fir_q7 ( const arm_fir_instance_q7 S,
const q7_t pSrc,
q7_t pDst,
uint32_t  blockSize 
)

Processing function for the Q7 FIR filter.

Parameters
[in]Spoints to an instance of the Q7 FIR filter structure
[in]pSrcpoints to the block of input data
[out]pDstpoints to the block of output data
[in]blockSizenumber of samples to process
Returns
none
Scaling and Overflow Behavior
The function is implemented using a 32-bit internal accumulator. Both coefficients and state variables are represented in 1.7 format and multiplications yield a 2.14 result. The 2.14 intermediate results are accumulated in a 32-bit accumulator in 18.14 format. There is no risk of internal overflow with this approach and the full precision of intermediate multiplications is preserved. The accumulator is converted to 18.7 format by discarding the low 7 bits. Finally, the result is truncated to 1.7 format.