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Scarface
Joined: 03 Dec 2013 Posts: 5
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Three phase PWM for AC motor with PIC18F4431 |
Posted: Tue Dec 31, 2013 11:17 am |
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Hi,
I'm making a project using pic18f4431 which drive three phase ac motor. I put pwm outputs in complimentary mode and everything is OK. But to drive the ac motor I need 120 degree offset between each inverter arm. So, can someone help me with code?
Code: | #include <18F4431.h>
#fuses INTRC_IO,NOWDT,PUT,BROWNOUT,NOLVP
#use delay(clock=8M)
#define POWER_PWM_PERIOD 40 // Gives 25 KHz pwm freq with PWM_CLK_DIV_4
void main()
{
float adc_val;
setup_power_pwm_pins(PWM_COMPLEMENTARY,PWM_COMPLEMENTARY,PWM_COMPLEMENTARY,PWM_OFF);
setup_power_pwm(PWM_UP_DOWN | PWM_CLOCK_DIV_4 | PWM_DEAD_CLOCK_DIV_2, 1, 0, POWER_PWM_PERIOD, 0, 1, 0);
setup_adc_ports(sAN1);
setup_adc(ADC_CLOCK_INTERNAL | ADC_CONT_A | ADC_WHEN_PPWM);
while(TRUE)
{
set_adc_channel(1);
delay_us(1);
adc_val = read_adc();
set_power_pwm0_duty((int16)((POWER_PWM_PERIOD *4) * (adc_val/255)));
set_power_pwm2_duty((int16)((POWER_PWM_PERIOD *4) * (adc_val/255)));
set_power_pwm4_duty((int16)((POWER_PWM_PERIOD *4) * (adc_val/255)));
}
} |
Best Regards! |
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Mike Walne
Joined: 19 Feb 2004 Posts: 1785 Location: Boston Spa UK
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Posted: Tue Dec 31, 2013 12:26 pm |
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We need lots more information about what you are trying to do.
1) What is the adc reading supposed to control?
2) Are you wanting to control motor speed?
3) What have you already tried?
4) What searches have you done?
5) ...............................
Mike |
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temtronic
Joined: 01 Jul 2010 Posts: 9243 Location: Greensville,Ontario
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Posted: Tue Dec 31, 2013 12:39 pm |
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There's a Microchip application note about doing it ! Had it on my desktop..opened it ,read a bit then ..decided to clean up the PC...now it's in 'some folder, somewhere' on this silly PC. Shouldn't be too hard to find at the uChip site though,faster than me trying to figure out just where I put it this morning.
hth
jay
+++++++++++++++++
Jay,
A reminder. Give a useful answer - not that you lost an appnote.
It's a help forum. Not a chat forum.
- Forum Moderator
+++++++++++++++++ |
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Scarface
Joined: 03 Dec 2013 Posts: 5
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Posted: Tue Dec 31, 2013 4:52 pm |
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Mike,
adc reading in code is for variable speed control. The idea in this project is exactly motor speed control. I have also current,voltage and temperature feedbacks and LCD display and there is no problem to write their source code. I want to generate three phase pwm which will drive my ac motor. What I've done is to set pwm in complimentary mode (T1, T3, T5-high; T2, T4, T6-low), but this iя not correct for three phase inverter - all pwms have same phase angle. So I need 120 degree offset between each inverter arm. I read CCS manual but I don't find any function for this.
T1....T3....T5
.|......|......|.
T2....T4....T6
Applications which I use are:
AC Induction Motor Fundamentals http://ww1.microchip.com/downloads/en/AppNotes/00887a.pdf
Controlling 3-Phase AC Induction Motors Using the PIC18F4431 http://ww1.microchip.com/downloads/en/AppNotes/00900a.pdf |
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Ttelmah
Joined: 11 Mar 2010 Posts: 19538
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Posted: Wed Jan 01, 2014 2:11 am |
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The point about Jay's post, is that there _is_ an app note.
He has lost it, but is pointing out that a quick search of the MicroChip site should find it, and this ought to be the starting point.
I think it is probably AN900 that he is thinking of (there are actually quite a few more for more complex control), which the original poster has already found.
In general the 'flowchart' of such notes gives a great key to how it needs to be done.
However I think there is a fundamental misunderstanding about how you do this from the original poster. You don't use the pulses of the PWM to directly drive the individual phases with just on/off. You synthesise a sinusoidal waveform by varying the mark/space of the PWM. You run the PWM, at something like 10KHz, and are changing the value fed to each of the three outputs on every cycle of this. Study how AN900 updates the pwm ratios....
Best Wishes |
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Mike Walne
Joined: 19 Feb 2004 Posts: 1785 Location: Boston Spa UK
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Posted: Wed Jan 01, 2014 3:42 am |
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Having found AN900 you need to read it carefully.
Ttelmah has drawn attention to the fundamental error in your understanding of what's required.
Each of the PWMs is varied to synthesise a sine wave.
It's these three sine wave which are 120 degrees out of step with each other.
The principal determinant of motor speed is the frequency of the sine waves, not the PWM ratio as you seem to think.
It's all in the app note.
Happy new year.
Mike |
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Scarface
Joined: 03 Dec 2013 Posts: 5
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Posted: Wed Jan 01, 2014 6:28 am |
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I know that synthesise a sinusoidal waveform is by varying the space of the PWM. Varying duty cycle of PWM I control sine waves and respectively induction motor. But to work three phase inverter you not have to allow transistors T1,T3,T5 or T2,T4,T6 to work at the same time. If they work at the same time they will burn. What I mean by wanting to put PWM offset like a picture I posted you can see this in this app http://www.tntech.edu/files/cesr/StudThesis/asuri/Chapter4.pdf . App explains fundamental princip of inverters. Look at from point 4.3 three phase inverter to the end of pdf and you'll understand what I want to do. |
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PCM programmer
Joined: 06 Sep 2003 Posts: 21708
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Posted: Wed Jan 01, 2014 7:39 am |
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Search the Microchip forum. Use Google to search for this:
Quote: | site:microchip.com/forums 3-phase pwm 18F4431 OR 18F2431 OR 18F4331 OR 18F2331 |
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Ttelmah
Joined: 11 Mar 2010 Posts: 19538
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Posted: Wed Jan 01, 2014 7:59 am |
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The only FET's that mustn't/won't be on at the same time, are the second one in each pair. So, using the numbers from Fig1, in AN900, PWM2 must not be on at the same time as PWM1. Similarly 2/3, and 4/5. However PWM3, and PWM1, _will_ be on at the same time, as will PWM1, and PWM4, at different parts of the cycle etc..
The point is that the individual PWM waveforms _won't_ display the relationship you are looking for. It is the combined 'effect' out, from the selection of mark/space ratio and which pairs are being driven, which has the 120 degree relationship....
Best Wishes |
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Mike Walne
Joined: 19 Feb 2004 Posts: 1785 Location: Boston Spa UK
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Posted: Wed Jan 01, 2014 8:22 am |
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Scarface wrote: | I know that synthesise a sinusoidal waveform is by varying the space of the PWM. Varying duty cycle of PWM I control sine waves and respectively induction motor. But to work three phase inverter you not have to allow transistors T1,T3,T5 or T2,T4,T6 to work at the same time. If they work at the same time they will burn. What I mean by wanting to put PWM offset like a picture I posted you can see this in this app http://www.tntech.edu/files/cesr/StudThesis/asuri/Chapter4.pdf . App explains fundamental princip of inverters. Look at from point 4.3 three phase inverter to the end of pdf and you'll understand what I want to do. |
No you're wrong. Ttelmah and I are saying the same thing.
What's NOT helping is the typo in the document you're reading.
The 1st three headings in table 4.1 SHOULD be S11, S21, S31 and NOT S11, S12, S31 as shown.
Mike |
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Scarface
Joined: 03 Dec 2013 Posts: 5
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Posted: Wed Jan 01, 2014 9:00 am |
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Ok let's say that I'm wrong and you're right.
This is ASM source code used in AN900 app. As you see there is PWM offeset exactly how I want to do.
Code: | ;*******************************************************************************
;UPDATE_PWM_DUTYCYCLES
;
;This routine will update the PWM duty cycle on CCPx according to the
;offset to the table with 0-120-240 degrees.
;This routine scales the PWM value from the table based on the frequency to keep V/F
;constant.
;*******************************************************************************
UPDATE_PWM_DUTYCYCLES
movf TABLE_OFFSET1,W ;Load the table offset for Phase 1
movf PLUSW0,W ;Use offset to access value in sine table via indirect addressing
mulwf FREQUENCY, W ;Table_value X Frequency
movff PRODH,PDC0H_TEMP ;Copy high product into temporary variable for PDC0H
movff PRODL,PDC0L_TEMP ;Copy low product into temporary variable for PDC0L
; movlw 0x1E ;Add 78h (1Eh shifted left two bits), in order to prevent 0 duty cycle
; addwf PDC0L_TEMP, F
; btfsc STATUS, C
; incf PDC0H_TEMP, F
UPDATE_PWM2
movf TABLE_OFFSET2,W ;Load the table offset for Phase 2
movf PLUSW0,W ;Use offset to access value in sine table via indirect addressing
mulwf FREQUENCY, W ;Table_value X Frequency
movff PRODH,PDC1H_TEMP ;Copy high product into temporary variable for PDC1H
movff PRODL,PDC1L_TEMP ;Copy low product into temporary variable for PDC1L
; movlw 0x1E ;Add 78h (1Eh shifted left two bits), in order to prevent 0 duty cycle
; addwf PDC0L_TEMP, F
; btfsc STATUS, C
; incf PDC0H_TEMP, F
UPDATE_PWM3
movf TABLE_OFFSET3,W ;Load the table offset for Phase 3
movf PLUSW0,W ;Use offset to access value in sine table via indirect addressing
mulwf FREQUENCY, W ;Table_value X Frequency
movff PRODH,PDC2H_TEMP ;Copy high product into temporary variable for PDC2H
movff PRODL,PDC2L_TEMP ;Copy low product into temporary variable for PDC2L
; movlw 0x1E ;Add 78h (1Eh shifted left two bits), in order to prevent 0 duty cycle
; addwf PDC0L_TEMP, F
; btfsc STATUS, C
; incf PDC0H_TEMP, F
TRUNCATE_PWM123 ;Truncate results of multiply to 10 uppermost bits
bcf STATUS,C ;discarding lower two bits and right justifying
rlcf PDC0L_TEMP,F
rlcf PDC0H_TEMP,F
rlcf PDC0L_TEMP,F
rlcf PDC0H_TEMP,F
rlcf PDC0L_TEMP,W
andlw 0x3
movff PDC0H_TEMP,PDC0L_TEMP
movwf PDC0H_TEMP
bcf STATUS,C
rlcf PDC1L_TEMP,F
rlcf PDC1H_TEMP,F
rlcf PDC1L_TEMP,F
rlcf PDC1H_TEMP,F
rlcf PDC1L_TEMP,W
andlw 0x3
movff PDC1H_TEMP,PDC1L_TEMP
movwf PDC1H_TEMP
bcf STATUS,C
rlcf PDC2L_TEMP,F
rlcf PDC2H_TEMP,F
rlcf PDC2L_TEMP,F
rlcf PDC2H_TEMP,F
rlcf PDC2L_TEMP,W
andlw 0x3
movff PDC2H_TEMP,PDC2L_TEMP
movwf PDC2H_TEMP
;testofPWM
; infsnz temp, f
; incf temp1, f
; btfss temp1, 2 ;if this bit is set temp1=4
; goto donewiththis
; clrf temp
; clrf temp1
;donewiththis
; movff temp, PDC0L_TEMP
; movff temp1, PDC0H_TEMP
; movlw 0x01
; movwf PDC0L_TEMP
; movlw 0x00
; movwf PDC0H_TEMP
; movlw 0xe8
; movwf PDC1L_TEMP
; movlw 0x03
; movwf PDC1H_TEMP
call CHECK_LIMITS
bsf PWMCON1, UDIS ;Disable updates to duty cycle and period
movff PDC0L_TEMP,PDC0L ;Transfer temporary values into duty cycle registers
movff PDC0H_TEMP,PDC0H
movff PDC1L_TEMP,PDC1L
movff PDC1H_TEMP,PDC1H
movff PDC2L_TEMP,PDC2L
movff PDC2H_TEMP,PDC2H
; movlw 0xFA
; movwf PDC0L
; movlw 0x00
; movwf PDC0H
; movlw 0xF4
; movwf PDC1L
; movlw 0x01
; movwf PDC1H
; movlw 0xEE
; movwf PDC2L
; movlw 0x02
; movwf PDC2H
bcf PWMCON1, UDIS ;Enable updates to duty cycle and period to update simultaneously.
return
;*******************************************************************************
;UPDATE_TABLE_OFFSET
;
;This routine Updates the offset pointers to the table after every access
;*******************************************************************************
UPDATE_TABLE_OFFSET
btfss FLAGS,OFFSET1_FLAG ;If set incr. on table
bra DECREMENT_OFFSET1
movlw (SINE_TABLE_ENTRIES-1) ;Check for the last value on the table
cpfslt TABLE_OFFSET1
bra CLEAR_OFFSET1_FLAG
incf TABLE_OFFSET1,F ;Increment offset1
bra UPDATE_OFFSET2
CLEAR_OFFSET1_FLAG
bcf FLAGS,OFFSET1_FLAG
DECREMENT_OFFSET1
dcfsnz TABLE_OFFSET1,F ;Decrement offset1
bsf FLAGS,OFFSET1_FLAG
UPDATE_OFFSET2
btfss FLAGS,OFFSET2_FLAG ;If set incr. on table
bra DECREMENT_OFFSET2
movlw (SINE_TABLE_ENTRIES-1) ;Check for the last value on the table
cpfslt TABLE_OFFSET2
bra CLEAR_OFFSET2_FLAG
incf TABLE_OFFSET2,F ;Increment offset2
bra UPDATE_OFFSET3
CLEAR_OFFSET2_FLAG
bcf FLAGS,OFFSET2_FLAG
DECREMENT_OFFSET2
dcfsnz TABLE_OFFSET2,F ;Decrement offset2
bsf FLAGS,OFFSET2_FLAG
UPDATE_OFFSET3
btfss FLAGS,OFFSET3_FLAG ;If set incr. on table
bra DECREMENT_OFFSET3
movlw (SINE_TABLE_ENTRIES-1) ;Check for the last value on the table
cpfslt TABLE_OFFSET3
bra CLEAR_OFFSET3_FLAG
incf TABLE_OFFSET3,F ;Increment offset3
return
CLEAR_OFFSET3_FLAG
bcf FLAGS,OFFSET3_FLAG
DECREMENT_OFFSET3
dcfsnz TABLE_OFFSET3,F ;Decrement offset3
bsf FLAGS,OFFSET3_FLAG
return
;*******************************************************************************
;Initialize PCPWM
; NOTES:
; 1) PTPER has 12-bit resolution, 4 LSBs of PTPERH and 8 bits of PTPERL
; 2) In edge aligned mode, PTMR reset to zero on match with PTPER
; 3) PDC has 14-bit resolution, 6 LSBs of PDCxH and 8 bits of PDCxL
; 4) Lower 2 bits of PDC compared to Q clocks
;
; 5) Resolution(of duty cycle)= log((Fosc/4)/Fpwm)/log(2) = log(5Mhz/20kHz)/log(2) = 8 bits
; so 6 LSBs of PDCxH and 2 MSBs of PDCxL will be used.
; (for 16kHz, resolution = log(5Mhz/16kHz)/log(2) = 8 bits, also.)
;
;*******************************************************************************
INIT_PCPWM
movlw b'00000000' ; PTCON0 is configured such that:
movwf PTCON0 ; a) Postscale value is 1:1
; b) PWM time base input is Fosc/4
; c) PWM time base mode is free-running for edge-aligned operation
movlw 0xF9 ; PTPERL and PTPERH are set up for a 20KHz PWM frequency.
movwf PTPERL ; PTPERH:PTPERL = ((Fosc/4)/(PWMfreq x PTMRps))-1
movlw 0x00 ; PTPERH:PTPERL = ((20MHz/4)/(20KHz x 1))-1 = 249d = F9h
movwf PTPERH
; movlw 0x37 ; PTPERL and PTPERH are set up for a 16KHz PWM frequency.
; movwf PTPERL ; PTPERH:PTPERL = ((Fosc/4)/(PWMfreq x PTMRps))-1
; movlw 0x01 ; PTPERH:PTPERL = ((20MHz/4)/(16KHz x 1))-1 = 311d = 137h
; movwf PTPERH
movlw b'01000000' ; PWMCON0 is configured such that:
movwf PWMCON0 ; a) PWM0, PWM1, PWM2, PWM3, PWM4, and PWM5 are enabled for output.
; b) All PWM I/O pairs are set to complimentary mode
movlw b'00000001' ;PWMCON1 is configured such that:
movwf PWMCON1 ; a) Special event trigger post-scaler is set to 1:1
; b) Special event trigger occurs when time-base is counting upwards
; c) Updates from duty cycle and period buffer registers are enabled.
; d) Output overrides via OVDCON are synchronous to the PWM timebase.
movlw b'00001010' ;1us deadtime instead of 2us
; movlw b'00010100' ;DTCON is configured such that:
movwf DTCON ; a) Clock source for dead-time is Fosc/2.
; b) Dead time = Dead time value / (Fosc/2) = 2uS.
; clrf DTCON ;DTCON for zero dead-time (relying on IRAMS cross-conduction prevention logic)
; movlw b'00000000'
movlw b'11111111' ;OVDCOND is configured such that there is no output override.
movwf OVDCOND
movlw b'00000000' ;OVDCONS is configured such that all PWM outputs are 0 upon power-up.
; movlw b'11111111' ;OVDCONS is configured such that all PWM outputs are 1 (inactive) upon power-up.
movwf OVDCONS
;FLTA is overcurrent fault, muxed via configuration bit to RC1
;FLTB is overvoltage fault on RC2
; bsf TRISC, 1 ;Ensure that RC1 is an input
; bsf TRISC, 2 ;Ensure that RC2 is an input
; movlw b'10000000' ;Fault A and FaultB are disabled.
; movlw b'10000011' ;Fault B is disabled
movlw b'10010001' ;Fault A and FaultB are enabled in catastrophic mode.
; movlw b'10110011' ;FLTCONFIG is configured such that:
movwf FLTCONFIG ; a) Enable fault condition on break-point for use with ICD2
; b) Enable FaultA in cycle-by-cycle mode
; c) Enable FaultB in cycle-by-cycle mode
; d) Fault A and Fault B disable PWM channels 0 to 5
movlw 0x00 ;SEVTCMPL and SEVTCMPH are clear.
movwf SEVTCMPL
movlw 0x00
movwf SEVTCMPH
; clrf PDC0L ;PDC0L, PDC1L, PDC2L, PDC3L, PDC0H, PDC1H, PDC2H, PDC3H
; clrf PDC1L ; are clear so that duty cycles are initially 0.
; clrf PDC2L
; clrf PDC3L
; clrf PDC0H
; clrf PDC1H
; clrf PDC2H
; clrf PDC3H
bsf PTCON1, PTEN ;PTEN bit in the PTCON1 is set to enable the PWM time base.
;----------------------
;infinite_loop
; goto infinite_loop
;----------------------
return
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This is link from microchip site where is AN900 and complete souce code https://www.microchip.com/stellent/idcplg?IdcService=SS_GET_PAGE&nodeId=1824&appnote=en020394 |
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temtronic
Joined: 01 Jul 2010 Posts: 9243 Location: Greensville,Ontario
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Posted: Wed Jan 01, 2014 9:52 am |
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comment: OK, I finally did find the apnote and it is AN900 and managed to loose 27,000+ PIC CCS files in the meantime,so I'm not exactly happy this new year...
Providing the asm code you show is compatible with your PIC, you code add it using the CCS instaruction..#asm..... something that CCS does allow and I've used in the past.
Another option is to 'decode' what it's doing and create similar C code.Good news is uChp has pretty good comments on what's going on. Yes, not exactly what a rookie programmer can easily do, but can be done,just takes some time.
Yet another option is to use additional hardware to make the 3 phase outputs.If you start with a 6* clock signal then feed that into a /6 counter, you'll get 3phases 120* apart.Sorry I don't have apart number or schematic to provide but it's an 'old school' way of doing it.You only need one PWM signal(6* desired frequency).
hth
jay |
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Mike Walne
Joined: 19 Feb 2004 Posts: 1785 Location: Boston Spa UK
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Posted: Wed Jan 01, 2014 11:15 am |
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Yes. The offset is forcing each PWM channel to look up a sine table value which is 120 degrees phase shifted from the other channels.
In the microchip code all three PWM channels are being set edge aligned.
There's nothing to stop T1, T3 & T5 turning on together. Nor for that matter T2, T4 & T6.
It's important T1/2 don't turn on together, (and of course T3/4 & T5/6).
If you try to prevent T1,3,5 coming on simultaneaously you'll likely end up with a huge DC component across at least one winding with equally disastrous results.
Mike |
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Scarface
Joined: 03 Dec 2013 Posts: 5
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Posted: Wed Jan 01, 2014 12:46 pm |
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Is there any way this code to be modified from ASM to CCS because I have no idea of assembler programing. Or my code to be written with offset.
The reason why T1,T3 and T5 haven't work together at the same time is because then the electrical circuit can't be closed. The Circuit always is between Power supply/Signal and ground but this case you haven't it. The second thing is that in this mode 100% you will burn out some of the electronic elements. Some is with T2,T4 and T6. I've seen blown inverters for this reason. You are right when you say that T1 and T2(3/4 or 5/6) don't be turn on together. The correct way of working is: two transistors up(T1,T3 or T5) and one down(T2,T4 or T6) or one up and two down at the same time. This is the reason why is set 120 degree offset. It keeps transistor from wrong work. You can see it and from the picture I posted. |
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Ttelmah
Joined: 11 Mar 2010 Posts: 19538
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Posted: Wed Jan 01, 2014 3:47 pm |
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The code is not exactly hard to modify. 50% of it is remmed out, and the values are just a matter of array lookups, multiplication, and loading the registers.
The point though is that the hardware does not ensure the transistors don't overlap. It is just the code that does this.
Best Wishes |
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