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Timing System
Timing System Applications
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Timing System components
Counting mechanisms Input capture mechanisms Output capture mechanisms
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Counting system
16-bit unsigned counter (TCNT) incremented at a fixed rate determined by two programmable bits (PR1 and PR0). The counter cannot be stopped or reset.
For an E clock of 2 MHz (= 500 ns period)
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Input Capture System
The 68HC11 has 3 input capture modules:
Each input Capture module has: And external input pin ICn
A flag bit Two edge control lines An interrupt mask bit A 16-bit input capture register
There are no directions register bits associated with PA2-0,These bits are always inputs
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Input Capture basic structure
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Actions occurring as a result of a capture event
1. The current TCNT value is copied into the input capture register (TICn)
2. The input capture flag is set (ICnF)
3. If the mask bit is armed (ICIn set to 1) an interrupt is requested
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Input Capture Registers
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Input Capture modes
IC1 IC2 IC3
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Input Capture flags
• When an input capture event (edge) of the type activated (TCTL2 reg.) occurs on the IC pin the corresponding input capture flag is set (IC1F, IC2F, IC3F) and the current value of TCNT is stored in the corresponding timer control register (TIC1, TIC2, TIC3).• Every time TCNT overflows from $FFFF to $0000, the TOF flag is set• The software can determine if an input capture event occurred by reading the flag registers
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Input Capture flags
The flags are cleared by writing a 1 into the specific flag bit we wish to clear
Do not use bset or TFLG1 |= 0x01 (no read-modify-write operations !)
If for example we had 0xFF in TFLG1 as a result of the OR we end up writing 0xFF in TFLG1 so we clear all the flags instead of the LSB only)
ldaa #$01staa $1023 TFLG1=0x01
example
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Input Capture masks
If the input capture flags are armed (IC1I, IC2I, IC3I, TOI) then an interrupt will be requested as soon as the flag is set
Interrupt mask for the TOF TCNT rate
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Input Capture Applications
Arm the flag bit so that an interrupt is requested on the active edge of an external signal
Perform two rising edge input captures and subtract the two measurement to get period
Perform a rising edge capture then a falling edge capture, and subtract the two measurements to get pulse width
…
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Real Time interrupt using Input Capture
0.693 x CT x (RA+2RB)
Example: Create a periodic interrupt (one interrupt every ms). Every time there is the interrupt we increment a global variable TIME
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Real Time interrupt using Input Capture
There is a latency between the rise edge of the interrupt and when the increment of TIME really occurs:
(1) finish the current instruction
(2) process the interrupt
(3) execute the interrupt handler (including changing TIME)
6811
Longest instruction: 41 cycles
Process the interrupt: 14 cycles
Execute handler: 28 cycles (our code)
Max latency: 83 cycles (=41.5 s)
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Real Time interrupt using Input Capture
The interrupt software:
(1) performs a poll (check the flag),
(2) acknowledge the interrupt (clear the flag),
(3) increments the global variable
set IC3 to be active on pos. edge and leave the others alone
make sure the interrupt flag for IC3 is clear
arm IC3 interrupt and leave the others alone
make sure the execution of the initialization software cannot be interrupted
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Real Time interrupt using Input Capture
If we jumped to the interrupt routine and theflag is not setthen there isan ERROR !!
Total 28
Poll the flag
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Real Time interrupt using Input Capture
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Period Measurement
Resolutionsmallest change in period that can reliably be measured
Precisionnumber of separate and distinguishable measurements that we can take (e.g. 65536 16 bits)
RangeThe minimum and maximum values that can reliably be measured
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16-bit period measurement with 500 ns resolution using input capture
The period is calculated as the difference in TIC1 values from on rising edge to the other
This method does not operate properly if the period is larger than 65535 cycle
The shortest period that can be handled is given by: num. cycles to process the interrupt + num. cycles of the handler
The resolution is 500 ns because the period must increase of at least this amount before the difference between TIC1 measurements can be appreciated
+V
-V
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32-bit period measurement with a 500 ns resolution using input capture
Every time the TCNT overflows from $FFFF to $0000, the TOF flag is set.
We can increase the precision of the period measurement by counting the number of TOF flag setting events during one period
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Pulse-width measurements
The basic idea is to cause an input capture event on both the rising and falling edges of an external signal
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Pulse width measurement using busy waiting
T = 0.45 (R+R1) C We chose R1 and C so that the resistance range 0 R
1Mmaps into 500 ns T 1000 s T = 0.45 R C T=500 ns R=1K
Multivibrator
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Pulse width measurement using busy waiting
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Pulse width measurement using busy waiting
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Pulse width measurement using interrupts
Both the rising and falling edges will generate an input capture interrupt
IC1 IC1
Rising = TIC1 PW = TIC1 - Rising
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Pulse width measurement using two input capture channels
The lower bound on the range is determined by the software overhead to process the input capture interrupt
The rising edge time will be measured by IC2 without the need of an interrupt routine, and the falling edge interrupt will be handled by IC1
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Output compare system
Each output compare module has: An external output pin OCn
A flag bit A force output compare control bit FOCn Two control bits (OMn, OLn) An interrupt mask bit A 16-bit output compare register
The 68HC11 has 5 output compare modules
There is a direction register bit for PA7/OC1 (DDRA7 bit in PACTL) and a direction register bit
for PA3/OC5 (DDRA3 bit in PACTL)
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Output compare basic structure
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Actions occurring as a result of an output compare event
An output compare event occurs when either: The 16-bit TCNT matches the the 16-bit OC register The software writes a 1 to the FOC bit
As a result of an output compare event:1. The OCn output signal change
2. The output compare flag OCnF is set
3. If the mask bit OCnI is armed an interrupt is requested
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Output compare registers
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Output compare modes and levels
The TCTL1 register determines what effect the output compare event will have (none, toggle, clear, set) on the output pins (OC1, OC2, OC3, OC4, OC5)
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Output compare flags
• The software can determine if an output compare event occurred by reading the flag registers
• The flags are cleared by writing a 1 into the specific flag bit we wish to clear
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Output compare mask
If the output compare flags are armed (OC1I, OC2I, OC3I, OC4I, OC5I,TOI) then an interrupt will be requested as soon as the flag is set
Interrupt mask for the TOF TCNT rate
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The pulse accumulator mechanism
• The output compare OC1, operates differently. It can also be used as pulse accumulator mechanism. On a successful OC1 event (TCNT=TOC1), the microcontroller can be programmed to set or clear any of the OCn pins.• OC1M tells which pin(s) will be affected by the OC1 event• OC1D specify the reulting value of the output pin(s) after an OC1 event
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Output compare applications
create square waves create variable duty cycles waveforms generate pulses implement time delays execute periodic interrupts …
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Fixed Time Delay
fixed is the number of cycles you wish to wait
1. read the current 16-bit TCNT
2. calculate TCNT + fixed
3. set the 16-bit output register to TCNT + fixed
4. clear the output compare flag
5. wait for the output compare flag to be set
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Periodic interrupt using output compare
Increments a global variable Time every 1 ms
2000 x 500 ns = 1ms
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Square wave generator
Fastest square waveform 2 × Total execution time
Total execution time = time to process the interrupt + time to execute the handler
for the 68HC11 is 14 cycles
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Square wave generator
OM3 = 0, OL3 =1Toggle output OC3
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Pulse Width Modulation
Average Current (= DC current)
Effective and popular mechanism for embedded systems to control external devices
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Pulse Width Modulator
duty cycle = high / (high + low)
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Pulse Width Modulator
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Pulse Width Modulator
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Pulse Width Modulator
Process interrupt: 14 cyclesExecute handler: 53-56 cyclesTotal Time T: 67-70 cycles
Both High and Low must be bigger than T
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Delayed pulse generation
Use the pulse accumulator
Disarm so that the output pulse occurs only once not every 65536 counts of TCNT
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Frequency Measurement
Basic idea:count the number of input pulses occur for a fixed amount of time
Use input capture to count the pulses Use output capture to create the fixed time
intervalcounter
fixed timef =
frequency resolution = f = 1
fixed time