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Transcript
PWM Pulse Width Modulation ME 4447/6405 November 6th, 2012 Ellen Qiulei Huang Juan Orphee Austin Farmer Outline • Introduction -- What is PWM? • Analog vs. Digital Actuation • Consideration on PWM frequency • Implementation on the HCS12 --Register Setup • Examples of PWM configuration using assembly and C -- Applications of PWM 2 Presenter: Ellen Qiulei Huang • Introduction -- What is PWM? • Analog vs. Digital Actuation • Consideration on PWM frequency • Implementation on the HCS12 -- Register Setup • Examples of PWM configuration using assembly and C -- Applications of PWM 3 Ellen Qiulei Huang What is PWM? • Pulse Width Modulation (PWM) is a technique for delivering partial power to a load via digital means. • The on-off behavior changes the average power of signal. • Output signal alternates between on and off within specified period. • http://www.youtube.com/watch?v=Lf7JJAAZ xEU 4 Ellen Qiulei Huang Duty Cycle A percentage measurement of how long the signal stays on. On Off VH Duty Cycle (D) VL Period (T) 5 Ellen Qiulei Huang Duty Cycle • Duty Cycle: Duty Cycle On Time 100% Period • Average signal : Vavg D VH 1 D VL (Usually, VL is taken as zero volts for simplicity.) On Off VH VL Duty Cycle (D) Period (T) 6 Ellen Qiulei Huang Duty Cycle Characteristic • The average value of a PWM signal increases linearly with the duty cycle 7 Ellen Qiulei Huang Types of PWM – Left Aligned • Lead edge is fixed, the trailing edge is modulated. On Off Vhi Vlo On Off Vhi Duty Cycle ~60% Period Vlo Duty Cycle ~30% Period 8 Ellen Qiulei Huang Types of PWM – Right Aligned • Trailing edge is fixed, lead edge is modulated. Off On Vhi Vlo Off On Vhi Duty Cycle ~60% Period Vlo Duty Cycle ~30% Period 9 Ellen Qiulei Huang Types of PWM – Center Aligned • Center of signal is fixed, both edges are modulated Off On Off Vhi Off On Off Vhi Duty Cycle ~30% Vlo Period Vlo Duty Cycle ~60% Period 10 Ellen Qiulei Huang Analog Generation of PWM • Analog PWM signals can be made by combining a saw- tooth waveform and a sinusoid •PWM output is formed by the intersection of the saw-tooth wave and sinusoid. •PWM toggles when sine equals saw-tooth. 11 Ellen Qiulei Huang Digital Generation - Delta Method • Limit signals are offset from a reference • When output signal reaches limits, PWM state changes 12 Ellen Qiulei Huang Digital Generation - Delta Method • Quantizer converts the difference between output and limits. • Quantizer can be realized with a comparator whose output is 1 or 0 if the input signal is positive or negative. 13 Ellen Qiulei Huang Digital Generation - Delta Sigma Method • PWM signal generated by Delta method • Error = Ref – PWM • Error is integrated. When integration signal reaches limit, PWM state changes. 14 Ellen Qiulei Huang Digital Generation - Delta Sigma Method 15 Ellen Qiulei Huang Choosing your PWM frequency Input signal (PWM) Ripple Output signal (actuator response) 16 Ellen Qiulei Huang Choosing your PWM frequency • Resolution: Inversely proportional to the number of distinct duty cycles you can generate for a given period • Transitions can only occur on a clock tick • Frequency limited by your clock and desired resolution • Example: 8 MHz clock, choose PWM to be 4 MHz • Limited resolution: only 3 duty cycles to choose from 17 Ellen Qiulei Huang Avoid ripple,on Resolution loss, Consideration PWM frequency Power loss, Lower Limits Human hearing Upper Limits 1. Must be at least 10 times higher than the control system frequency 2. Higher than 20kHz – audible frequency of sounds to avoid annoying sound disturbances. 3. If too low the motor is pulsed, not continuous, because the motor’s inductance can not maintain the current 4. Inverse of frequency should be much less than the motor/load time constant 5. Higher error from ripple voltages 1. If too high the inductance of the motor causes the current drawn to be unstable 2. MOSFET transistor generates heat during switching 3. Limited by resolution of controller 4. Eddy currents generated in electromagnetic coils which lead to adverse heating 5. Heat losses in electromagnetic materials is proportional to frequency squared 18 Ellen Qiulei Huang Advantages of PWM • Average value proportional to duty cycle, D • Low power used in transistors used to switch the signal • Fast switching possible due to MOSFETS and power transistors at speeds in excess of 100 kHz • Digital signal is resistant to noise • Less heat dissipated versus using resistors for intermediate voltage values 19 Ellen Qiulei Huang Disadvantages of PWM • • • • Cost Complexity of circuit Voltage spikes Susceptible to Electromagnetic Interference 20 Presenter: Juan Orphee • Introduction -- What is PWM? • Analog vs. Digital Actuation • Consideration on PWM frequency • Implementation on the HCS12 --Register Setup • Examples of PWM configuration using assembly and C -- Applications of PWM 21 Juan Orphee Pulse Width Modulator: PWM8B6CV1 • Use Port P • Six 8-bit channels or three 16-bit channels for greater resolution • Each channel produces an independent PWM signal • Two choices of clock sources per channel which provides for a wide range of frequencies Juan Orphee PWM Block Diagram -Each channel needs setup of the following registrars: 1) Enable/disable 2) Signal Polarity 3) Clock A or SA, B or SB 4) Prescale A and B clocks 5) Center Alignment Enable 6) Control Register 7) Prescale SA and SB clocks 8) Counter 9) Period Define PWM signal 10)Duty Cycle 11)Emergency Shutdown Vhi Duty Cycle Vlo Period PWM Register Memory Map Juan Orphee Juan Orphee 1-PWM Enable Register (PWME) • PWME in address: $00E0 • Set PWMEx to 1 to enable the channel • Set PWMEx to 0 to disable the channel Juan Orphee 2-PWM Polarity Register (PWMPOL) • PWMPOL in address: $00E1 • Set PPOLx to 0, signal goes from low to high • Set PPOLx to 1, signal goes from high to low Signal Starts Here Zero Line Juan Orphee 3-PWM Clock Select Register (PWMCLK) • • • • • PWMCLK in address: $00E2 Set PCLK(5/4/1) 0 to use clock A Set PCLK(5/4/1) 1 to use clock SA Set PCLK(3/2) 0 to use clock B Set PCLK(3/2) 1 to use clock SB Note: choice of Prescale will determine clock selection Juan Orphee 4-PWM Prescale Clock Select Register (PWMPRCLK) • Located at $00E3 • Used to prescale clocks A and B Prescaler = Bus Clock Frequency (2N -1) × PWM Frequency Desired PWD Frequency N = bit resolution -Similar for Clock B Bus Clock HCS12 = 8 MHz -If calculated prescaler > 128 then use clock SA -How to convert time (e.g. in seconds) to cycles? Time (sec) x Clock Frequency = Time (sec) x (Buss Clock/Prescaler) Computing a Prescaler Duty Cycle Period Time per clock cycle (sec) = Prescaler x Time (sec) per bus clock cycle 125x10(-9) sec for HCS12 T (sec) -Resolution = Maximum Clock Counts -Example: An 8 bit counter can count 2^N-1 = 255 clock cycles PWM Frequency = 1 1 = PWM Period (Time per clock cycle) ×(Resolu PWM Frequency = 1 Prescaler × Time per Bus clock cycle ×(Reso lution) tion) Bus Clock Frequency PWM Frequency = (Prescaler) ×(Resolution) Prescaler = Bus Clock Frequency (2 -1) × PWM Frequency N 29 Juan Orphee 5-PWM Center Align Enable Register(PWMCAE) • • • • Located at $00E4 Set CAEx to 0 for left align signal Set CAEx to 1 for center align signal Note: – Can only be set when channel is disabled Juan Orphee Left vs. Center Aligned Not To Scale PWM Signal Starts Juan Orphee 6-PWM Control Register (PWMCTL) • • • • • • • PWMCTL : Located at $00E5 Set CONxy to 0 to keep 6 PWM channels separate (8-bit) Set CONxy to 1 to concatenate PWM channels x and y together (16-bit). x becomes the high byte and y becomes the low byte Channel y determines the configuration Bits PSWAI and PFRZ set either wait or freeze mode Note – Changes only occur when both channels are disabled Juan Orphee 7-PWM Scale A Register (SA Clock) (PWMSCLA) • Located at $00E8 • Programmable scaling of clock A to generate clock SA • Note Juan Orphee PWM Scale B Register (PWMSCLB) • Located at $00E9 • Programmable scaling of clock B to generate clock SB • Note Juan Orphee 8-PWM Channel Counter Register (PWMCNT) • • • • • Located at $00EC through $00F1 One per channel It tracks the cycle counts When channel is enabled up-count starts Note – Writing to counter while a channel is enable can cause irregular PWM cycles Juan Orphee Counter: Left vs. Center Aligned PWM Signal Starts • In the left aligned mode, the PWM counts up until (period-1) and resets to zero. • In the center aligned mode, the PWM counts up until (period-1) and counts down to zero. • Note: Period (PWMPER) is expressed in number of cycles Juan Orphee 9-PWM Channel Period Register (PWMPER) =$00F2 • • • • Located at $00F2 through $00F7 PWMPERx Store a hexadecimal value to limit maximum value of counter Note : Changes occur when one of following happen – Current period ends – Counter is written to – Channel is disabled What is my PWMPER? PWMPER (cycles) = PWM Period(sec) x Clock Freq(cycles/sec) Juan Orphee 10-PWM Channel Duty Register (PWMDTY) • Located at $00F8 through $00FD • Store a hexadecimal value to control when signal changes • Changes occur when: – Current period ends – Counter written to – Channel is disabled • e.g for 60% duty cycle: PWMDTY = 0.6xPWMPER (in cycles) Juan Orphee 11-PWM Shutdown Register (PWMSDN) $00FE Presenter: Austin Farmer • Introduction -- What is PWM? • Analog vs. Digital Actuation • Consideration on PWM frequency • Implementation on the HCS12 - Register configuration • Example of PWM configuration using Assembly and C Code • Applications of PWM 40 Austin Farmer PWM Configuration Example • • • • Use PWM Channel 0 Positive polarity (signal goes from high to low) Left aligned output Frequency: 40 kHz – Period = 1/Frequency = 1/40 kHz = 25 μs • Choose clock source using resolution: – Bus clock frequency: 125 ns 25 μs / 125 ns = 200 cycles – 200 < 255, select clock A with prescaler = 1 • Duty Cycle = 50% – (50% * 200 cycles) = 100 cycles 41 Austin Farmer Configuration Example: Assembly Code PWME PWMPOL PWMCLK PWMPRCLK PWMCAE PWMPER0 PWMDTY0 EQU EQU EQU EQU EQU EQU EQU $00E0 $00E1 $00E2 $00E3 $00E4 $00F2 $00F8 ORG LDAA STAA LDAA STAA STAA STAA LDAA STAA LDAA STAA LDAA STAA ... $1000 #$01 PWMPOL #$00 PWMCAE PWMCLK PWMPRCLK #$C8 PWMPER0 #$64 PWMDTY0 #$01 PWME * * * * * * * 1-PWM Enable Register 2-PWM Polarity Register 3-PWM Clock Select Register 4-PWM Prescale Clk Select Reg. 5-PWM Center Align Enable Reg. 9-PWM Channel 0 Period Register 10-PWM Channel 0 Duty Register *Positive polarity (starts high) *Left aligned output *Use Clock A *Clock A prescaler = 1 *Period =(25μs/125ns)= 200 = $C8 *Duty cycle=(200*50%)= 100 = $64 *Enable PWM Channel 0 Austin Farmer Configuration Example: C Code #include <hidef.h> /* common defines and macros */ #include <mc9s12c32.h> /* derivative information */ #pragma LINK_INFO DERIVATIVE “mc9s12c32” // Set up chip in expanded mode MISC = 0x03; PEAR = 0x0C; MODE = 0xE2; //Set up PWM Registrer PWMCLK = 0; // Sets source clock to clock A PWMPOL = 1; // Positive Polarity (signal goes from high to low) PWMCTL = 0; // Makes all channels 8-bit PWMCAE = 0; // Signals are left aligned PWMPER0 = 200; // Sets the period of the signal to 200 clock cycles PWMDTY0 = 100; // Makes the duty cycle 100 clock cycles (50% of 200) PWMPRCLK = 0; // Sets the prescaler to 1 PMWE = 1; // Enables and starts Channel 0 of PWM …. 43 Austin Farmer Motivation for PWM • In the past, motors were controlled at intermediate speeds by using variable resistors to lower delivered power (inefficient) – Example: Foot pedal on sewing machines is a variable resistor connected in series to control speed • PWM provides a more compact way of applying adjustable power to devices 44 Austin Farmer Applications of PWM • Voltage regulation • DC Motors • Telecommunications • Audio and Video Effects 45 Austin Farmer Application: Voltage Regulation • PWM is used in efficient voltage regulators • With appropriate duty cycle, the output will approximate voltage at the desired level • Switching noise can be filtered 46 Austin Farmer Application: DC Motors • Commonly used to control the speed of a DC motor • Continuous application of PWM cycle results in average voltage being applied to motor • Output speed of motor is proportional to input voltage • http://www.youtube.com/watch?v=Lf7JJAAZx EU • Used in Lab 3 47 Austin Farmer Application: Telecommunications • Pulses of various lengths will be sent at regular intervals (the carrier frequency of the modulation) • The widths of the pulses correspond to specific data values encoded at one end and decoded at the other • Leading edge of the data used as clock because small offset is included • More resistant to noise effects than binary data alone 48 Austin Farmer Applications: Audio and Video • In audio circuits, PWM can produce an effect similar to a chorus • Used in new class of efficient audio amplifiers • PWM dimming provides superior color quality in LED video display (millions of colors) 49 Questions?