; ************************* TWIST24 ****************************** ; ; Purpose of routine is to evaluate ; ; A*X0 + B*Y ; X1 = --------- ; A + B ; ; Such as A+B = 2^n ; ; Simplified this formula will then become ; ; A*X0 + ~A*Y + Y ; X1 = --------------- ; 2^n ; ; Where: ; X1 - is new recursive lowpassed filter value ; X0 - is previous lowpassed filter value ; Y - is new value ; A,B are weight factors, if A is large relative to B ; then more emphasis is placed on the average ( filtered ) value. ; If B is large then the latest sample are given more weight. ; ~A is A's bitwise complement ; ; ; X0,X1,Y are 24 bit variables ; A+B = 2^8 = 256 for this routine ; ; By Tony Kübek 2000-05-23, based on routine 'twist.asm' by ; Scott Dattalo ( BTW Thanks for sharing :-) ) ; ; **************************************************************** ; ; NewSample = Y ( 4 byte ram, 3 byte data ) ; OldFilter = X0 ( 4 byte ram, 3 byte data ) ; NewFilter = X1 ( 4 byte ram, 3 byte data ) ; FilterWeight = A ( 1 byte ram, how much weight that is placed on old filtered value ) ; ; * variables not really needed but used in example * ; FilterCounter = 1 byte, counter to increase step responce. ; UpdateCounter = 1 byte, how many samples between 'global' updates ; AD_NewValue = 3 byte ram, last 24 bit reading from AD/or similar ( copied ; to NewSample, in case AD_NewValue should be used for other purposes ) ; AD_DataVal = 3 byte ram, filtered value updated after UpdateCounter samples ; _AD_DataReady = 1 bit, set when AD_DataVal is updated ; #define UPDATE_COUNT 0x20 ; 32 samples between global updates #define FILTER_WEIGHT 0x80 ; filterweight, i.e. 'A' in example above org $10 AD_NewValue ds 3 NewSample ds 4 ; copy of AD_Newvalue, used locally OldFilter ds 4 ; previous value of filtering ( NewFilter from last run ) NewFilter ds 4 ; the new filtered value FilterWeight ds 1 ; how much weight that should be posed on old value FilterCounter ds 1 ; to increase step responce UpdateCounter ds 1 ; how often we want an global update AD_DataVal ds 3 ; the global update location Bitvars ds 1 ENDC #define _AD_DataReady BitVars,0 ;++++++++++++ ; ; ADD_FSR_FILTER - Adds 32 bit value pointed to by FSR to NewFilter ; FSR must point to LEAST significant byte, FSR-3 is most significant ; ADD_FSR_FILTER MACRO ; 14-17 instructions ; add value pointed to by FSR to filter mov W, INDF ; get lowest byte add NewFilter+3, W ; add to filter sum lowest byte dec FSR mov W, INDF ; get next byte snb C ; if overflow movsz W, ++INDF ; increase source add NewFilter+2, W ; and add to dest. dec FSR mov W, INDF ; get next byte snb C movsz W, ++INDF add NewFilter+1, W dec FSR mov W, INDF ; get msb snb C movsz W, ++INDF add NewFilter, W ENDM ;++++++++++++ ; ; DIV_FILTER_BY2 - Divide NewFilter by 2 ; ; DIV_FILTER_BY2 MACRO ; 5 instructions ; right shift filter value by 1 ( i.e. divide by 2 ) clrb C ; clear carry ; divide by 2 rr NewFilter rr NewFilter+1 rr NewFilter+2 rr NewFilter+3 ENDM ;++++++++++++ ; ; MUL_NEWOLD_BY2 - Multiply OldValue and NewSample with 2 ; ; MUL_NEWOLD_BY2 MACRO ; 10 instructions ; right shift filter value by 1 ( i.e. divide by 2 ) clrb C ; clear carry ; multiply old value with 2 rl OldFilter+3 rl OldFilter+2 rl OldFilter+1 rl OldFilter ; multiply new value with 2 clrb C ; clear carry rl NewSample+3 rl NewSample+2 rl NewSample+1 rl NewSample ENDM org $0000 jmp INIT ; ** interupt routine for data collection org $0004 INT ; get data from AD call GET_AD_DATA ; not included ! ; for each sample, copy to AD_NewValue ; and call filter once call TWIST24 reti ; cold start vector INIT ; only 'dummy' code here clrb _AD_DataReady ; clear data ready flag ; Note, this will inilialize the filter to gradually use ; no filtering to 'full' filtering ( increase once for each sample ) ; mov W, #FILTER_WEIGHT mov FilterCounter, W clr FilterWeight MAIN_LOOP ; wait for some data from AD or similar sb _AD_DataReady ; check if data available jmp MAIN_LOOP ; nope ; filtered data available ; do whatever needs to be done.. clrb _AD_DataReady ; clear data ready flag jmp MAIN_LOOP ;++++++++++++ ; ; TWIST24 - Variable 24 bit lowpass filter, caculates new lowpassed value in NewFilter, ; by weighing previous filtervalue and NewSample according to FilterWeight ; If FilterWeight is large more emphasis is placed on oldfiltered value ; Maximum value for FilterWeight is 255 ( i.e. 8 bit variable ). ; FilterWeight = 0 -> NewFilter = 0/256 of OldFilter + 256/256 of NewSample, i.e no filtering ; FilterWeight = 255 -> NewFilter = 255/256 of OldFilter + 1/256 of NewSample, i.e. full filtering ; NOTE: Previous filtered value should be kept in NewFilter as it is used for next pass. ; TWIST24 ; about 252-285 instructions executed ( with global update and copying of new datavalue ) ; roufly 57 us at XTAL 20 Mhz ; ! uses FSR ! ; Ramp function, uses an extra ram variable FilterCounter that ; increases the FilterWeight until itself zero ; Usage: Initialise to FilterWeight, then a speedier time to target will ; be accomplished(step responce). During run, if for any reason an high ramp ; is detected ( or loss of readings ) this could be re-initialised to any ; value equal or less than FilterWeight to achive quicker step responce. ; NOTE : Filterweight must then ALSO be initialised so that the following ; is fulfilled: FilterCounter + FilterWeight = DesiredFilterWeight test FilterCounter snb Z jmp TWIST_GO decsz FilterCounter inc FilterWeight TWIST_GO ; Copy previous filtered value ( note previous value is multiplied by 256 ; i.e. only copy top three bytes of source to lowest three bytes of dest. ) mov W, NewFilter mov OldFilter+1, W mov W, NewFilter+1 mov OldFilter+2, W mov W, NewFilter+2 mov OldFilter+3, W ; copy new value from AD to 'local' variable and add it it ; to filter as start value mov W, AD_NewValue ; get top byte of new reading mov NewSample+1, W ; store in local variable mov NewFilter+1, W ; also add this as start value to new filter mov W, AD_NewValue+1 ; mov NewSample+2, W ; mov NewFilter+2, W ; mov W, AD_NewValue+2 ; mov NewSample+3, W ; mov NewFilter+3, W ; clr NewFilter ; clr OldFilter ; clear top bytes ( we only have a 24 bit filter ) clr NewSample mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.0 ; check if value that should be added is new or old mov FSR, W ; adress for old value already in W ADD_FSR_FILTER ; add it MUL_NEWOLD_BY2 ; upshift old and new value, 10 instr. mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.1 ; check if value that should be added is new or old mov FSR, W ; old value added to filter, adress in W ADD_FSR_FILTER ; add it MUL_NEWOLD_BY2 ; upshift old and new value, 10 instr. mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.2 ; check if value that should be added is new or old mov FSR, W ; old value added to filter, adress in W ADD_FSR_FILTER ; add it MUL_NEWOLD_BY2 ; upshift old and new value, 10 instr. mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.3 ; check if value that should be added is new or old mov FSR, W ; old value added to filter, adress in W ADD_FSR_FILTER ; add it MUL_NEWOLD_BY2 ; upshift old and new value, 10 instr. mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.4 ; check if value that should be added is new or old mov FSR, W ; old value added to filter, adress in W ADD_FSR_FILTER ; add it MUL_NEWOLD_BY2 ; upshift old and new value, 10 instr. mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.5 ; check if value that should be added is new or old mov FSR, W ; old value added to filter, adress in W ADD_FSR_FILTER ; add it MUL_NEWOLD_BY2 ; upshift old and new value, 10 instr. mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.6 ; check if value that should be added is new or old mov FSR, W ; old value added to filter, adress in W ADD_FSR_FILTER ; add it MUL_NEWOLD_BY2 ; upshift old and new value, 10 instr. mov W, #NewSample+3 ; get adress for new value mov FSR, W ; setup FSR mov W, #OldFilter+3 ; get adress for old value to W snb FilterWeight.7 ; check if value that should be added is new or old mov FSR, W ; old value added to filter, adress in W ADD_FSR_FILTER ; add it ; 235-268 instructions to get here ; check for rounding sb NewFilter+3.7 ; test top bit of lowest byte jmp TWIST24_EXIT ; add one to filter to have proper rounding mov W, #$01 add NewFilter+2, W snb C add NewFilter+1, W snb C add NewFilter, W TWIST24_EXIT ; check for update decsz UpdateCounter ret ; update global filter mov W, NewFilter+2 mov AD_DataVal+2, W mov W, NewFilter+1 mov AD_DataVal+1, W mov W, NewFilter mov AD_DataVal, W ; set data ready flag setb _AD_DataReady ; reinitialise update counter mov W, #UPDATE_COUNT ; number of samples between global update mov UpdateCounter, W ret
file: /Techref/scenix/lib/math/dsp/iir-24b-256s-tk_sx.htm, 9KB, , updated: 2004/6/10 13:40, local time: 2024/11/22 21:38,
3.149.29.98:LOG IN
|
©2024 These pages are served without commercial sponsorship. (No popup ads, etc...).Bandwidth abuse increases hosting cost forcing sponsorship or shutdown. This server aggressively defends against automated copying for any reason including offline viewing, duplication, etc... Please respect this requirement and DO NOT RIP THIS SITE. Questions? <A HREF="http://massmind.org/techref/scenix/lib/math/dsp/iir-24b-256s-tk_sx.htm"> SX Microcontroller DSP Math Method - 24bit 256 step IIR filter by Tony Kübek</A> |
Did you find what you needed? |
Welcome to massmind.org! |
Welcome to massmind.org! |
.