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TIMERS / COUNTERS
- Two 16 bit timer/counters- Can be programmed independently as – timer or event counter.- Four-SFR’s connected with TIMER/COUNTER operation- TMOD – Timer Mode Register- TCON – Timer Control Register- TH0, TL0 – Timer/Counter - 0- TH1, TL1 – Timer/Counter - 1- Two pins of 8051 connected with Timer/counter.
- INT0 and INT1 are also used for controlling the timer/counters.
Timer OperationTimer Register (TH0, TL0 or TH1, TL1) incremented every m/c cycle. Thus working at increment frequency of 1/12 of oscillator frequency ( for 12 oscillator machine cycle ). Any preset value i.e. initial count can be loaded to TH0, TL0 or TH1, TL1.
For Example – Clock frequency = 12 MHZClock period = 1/12 µ secMachine cycle time = 1 µ sec
Thus timer register will be incremented every microsecond.- If timer is initialized to 0000HMax. count = FFFFHmax. time measured = 216 µ sec
- May correspond to event like• Passing of railway coach from a point – axle counter • Rotation of speedometer cable
– speedometer of vehicle • No. of persons visiting exhibition.
- T0, T1 scanned every m/c cycle• nth m/c cycle – T1 or T0 = High• (n+1)th m/c – T1 or T0 = Low• Timer 0 or timer 1 incremented in (n+1)th m/c cycle
- Count frequency = min 2 m/c cycle per count- T0- P3.4, T1- P3.5
Counter Operation
In 12 MHz 8051 – m/c cycle = 1 µ sec- 8051 can count at the rate of 2 µ sec per count or higher- Any event when takes less than 2 µ sec may go unnoticed- C/T bit of TMOD selects Timer or counter operation for Timer 0
or Timer 1.- Timer/Counter operations are controlled by
- Gate bit of TMOD- TR0 bit of TCONWhen Gate = 0 then
TR0, TR1 act as Timer run control bits.
2 m/c cycle
- Thus make Gate = 0 in TMOD By making TR0 (TCON. 4) or TR1 (TCON. 6) = 1 . through instruction, Timer/Counter 0 or Timer/Counter 1 may be started.
- For starting and stopping the Timer/Counter from outside through hardware. Make Gate = 1, TR0 = 1 through software.
- By making INT0 or INT1 pin High will start Timer/Counter 0 or Timer/Counter 1 Make INT0 or INT1 Low to stop the Timer/Counter. INT0 - P3.2 INT1 - P3.3
As value in Timer register rolls from all ones (i.e. FFFFH) to all zero’s (i.e. 0000H) interrupt flag (TF0 or TF1) will be set.
- TF0 (for Timer 0) and TF1 (for Timer 1) are bits of TCON SFR. IF Timer 0 or Timer 1 interrupt is enabled then
program control will branch to interrupt servicing routine.
Timer modes - 4 modesMode 0 - 13 bit counterMode 1 - 16 bit counterMode 2 - 8 bit counter + auto reloadMode 3 - Split operation – Timer 0
TimerRegister
TF0 Interrupt
Program
Timer ISR
RETI
- Modes are set by M1 M0 bits of TMOD register. Mode 0 - 13 bit counter operation
- TH0, TL0 (for Timer 0) or TH1, TL1 (for Timer 1) used as 13 bit counter.
- All 8 bits of TH0 or TH1- 5 lower bits of TL0 or TL1
are used, for counting.- When count rolls over from all 1’s to all 0’s, - interrupt flag TF0 or TF1 is set.
OSC ÷ 12
TH0(8 bits) TF0TL0
(5 bits)
C/T = 0
C/T = 1
T0 pinControl
Interrupt
TR0
Gate
INT0 pinFigure Timer 0, mode 0 - 13-bit counter
In above figure when C/T = 0 - timer operation count incremented every m/c cycle.
providedTR0 (TCON. 4) or TR1 (TCON. 6) = 1
and Gate (TMOD. 3) or (TMOD. 7) = 0Other way is-
- TR0 or TR1 =1- Gate = 1 and INT0 or INT1 = 1
- Thus by sending Logic High signal on INT0 (or INT1) pins Timer 0 or Timer 1 can be started.
- This can be used for finding pulse width in the following way. C/T = 0 – Timer operation TR0 or TR1 = 1Gate = 1Source of pulse connected to INT0 or INT1 pin
- When pulse goes high timer starts counting at the rate 1/12 clock frequency
- Which pulse goes low – Timer stops.INT0 or INT1 = Low - causes interrupt.
- ISR can read the timer value.- ISR can store the timer value and process it as
required by the application.
TimerStarts
TimerStops
+ InterruptGenerated
Mode 1 – 16 bit counter
Figure Timer 0, mode 1 - 16-bit counter.
OSC ÷ 12
TH0(8 bits) TF0TL0
(8 bits)
C/T = 0
C/T = 1
T0 pinControl
Interrupt
TR0
Gate
INT0 pin
- Operation same as mode 0 except that all bits of TH0, TL0 or TH1, TL1 are used.When count rolls over from all 1’s to all 0’s – TF0 or TF1 interrupt flag is set.- Causes interrupt if enabled.
Mode 2 – 8 bit operation with auto reload
Figure Timer 0, mode 2 - autoreload.
OSC ÷ 12
TL0(8 bits) TF0
C/T = 0
C/T = 1
T0 pinControl
Interrupt
TR0
Gate
INT0 pin
TH0(8 bits)
- Only TL0 or TL1 are used i.e. 8 bit counting.- Initial preset value is loaded to TH0 or TH1 by
software.- The value is loaded to TL0 or TL1 by hardware
automatically before starts of counting.- When count rolls from all 1’s (i.e. FFH) to all 0’s (i.e.
00H)- TF0 or TF1 flag is set- Preset value in TH0 or TH1 is reloaded to TL0 or TL1
- Operation i.e. Counting starts automatically.
Mode 3 – Split operation – Timer 0
Figure Timer 0, mode 3-split to two 8-bit counters.
OSC ÷ 12
TL0(8 bits) TF0
C/T = 0
C/T = 1
T0 pinControl
Interrupt
TR0
Gate
INT0 pin
(1/12) fosc
(1/12) fosc
TH0(8 bits) TF1
Control
Interrupt(1/12) fosc
TR1
- When Timer 0 is put in mode 3 - Acts as two 8 bit counters i.e. TL0 and TH0
become two separate counter.
TL0 – 8 bit operation in mode 0 or mode 1 (Timer or Counter) controlled by C/T, TR0, Gate, INT0– Sets TF0 when count rolls to all 0’s from all 1’s.
TH0 – Timer function only. – Controlled by TR1 i.e. starts when TR1 = 1.When count rolls to all 0’s from all 1’s – TF1 flag is
set.
Note – TR1 and TF1 are used in Timer 0 (TH0) even though they are
bits for Timer 1. When Timer 1 is put in mode 3 – It
just holds the preset count – same as TR0 = 0 i.e. opening the
switch.[Modes 0, 1 and 2 are mostly used]
Timer Mode Control Register - TMOD
7 6 5 4 3 2 1 0
Gate C/T M1 M0 Gate C/T M1 M0
Timer 1 Timer 0Bit no.
M1 and M0 specify the mode as follows:M1 M0 Mode Description in brief
0 0 0 13-bit counter
0 1 1 16-bit counter
1 0 2 8-bit counter with autoreload
1 1 3 Split Timer 0 into two 8-bit counters or to stop Timer 1
Symbol
If C/T = 1, the timers function as counters to count the negative transitions at T0 or T1 pins.If C/T = 0, the timers function as timers, that is, they basically count the number of machine cycles.Gate = 0 means that the timer is controlled by TR1 or TR0 only, irrespective of INT0 or INT1.Gate = 1 means that the timer control will depend on INT0 or INT1 and also on TR0 or TR1 bits
When data is written it gets latched.TMOD is used for setting mode bits M1, M0, Gate bit and C/T for Timer 0 and Timer 1.Bit 0 to 3 for Timer 0.Bit 4 to 7 for Timer 1.
Timer Control Register - TCONBit 0 to 3 – used for interrupt functionsBit 4 to 7 – used for setting TR0, TR1 by software- Setting TF0, TF1 by counter i.e. hardware When count rolls from all 1’s to all 0’s.
7 6 5 4 3 2 1 0
TF1 TR1 TF0 TR0 IE1 IT1 IE0 IT0Bit no.
Symbol
TF1: Timer 1 overflow flag. Set by hardware when the timer/counter overflows.Cleared by hardware when the processor vectors to the interrupt routine.
TR1: Timer 1 run control bit. Set/cleared by software to turn the timer/counter on/off.
TF0: Timer 0 overflow flag. Set by hardware when the timer/counter overflows.Cleared by hardware when the processor vectors to the interrupt routine.
TR0: Timer 0 run control bit. Set/cleared by software to turn the timer/counter on/off.
Example – a. Configuring Timer/Counter using TMOD
7 6 5 4 3 2 1 0
Gate C/T M1 M0 Gate C/T M1 M0
Timer 1 Timer 0
C/T = 0M1 M0 = 00Gate = 0
C/T = 1M1 M0 = 01Gate = 0
TR1 TR0
TMOD = 0 0 0 0 0 1 0 1 = 0 5 H MOV TMOD, #05H
TIMER 1 - TIMERMode = 00(13 bit operation)
TIMER 0 - CounterMode = 01(16 bit operation)
- Work out the preset value = ABCDH – Timer 0- Load the preset value = 0000H - Timer 1
Make TR0 = 1, TR1 = 1TCON = 0 1 0 1 0 0 0 0 = 5 0 H MOV TCON, #50H or SETB TCON.4
SETB TCON.6
c. Start Timer/Counter through TR0, TR1
TCON =
7 6 5 4 3 2 1 0TF1 TR1 TF0 TR0 IE1 IT1 IE0 IT0
Timer Interrupt
- Following tasks need to be done.Preset value to be loaded to Timer RegisterTimer interrupt flag (TF0 or TF1) to be cleared
d. When count value in Timer Register transits from all 1’s to all 0’s
For continuous operation of Timer/CounterTime clockPulse train generation etc.
- Can be achieved in 2 ways:
1. - Check Timer interrupt flag in loop. JNB TCON.5, $ or JNB TCON.7, $- When interrupt flag is set then clear the flag. CLR
TCON.5 or CLR TCON.7- Load the preset count and restart
SJMP to b
2. Write ISR for Timer 0 or Timer 1 and store at location 000BH (for Timer 0) or 001BH (for Timer 1)- Enable Timer 0 or Timer 1 interrupt by making bits ET0 (IE.1) or ET1(IE.3) = 1. SETB IE.1 or SETB IE.3- When TF0 or TF1 is set- Interrupt will occur and program will branch to ISR location (000BH for Timer 0) or (001BH for Timer 1).
- ISR- clear flag TF0 or TF1- load preset value- Restart timer/counter RETI
Step d will be different for different applications.
Example -1- Generate a square wave of 50% duty cycle at pin p1.7. Use
Timer 1 to generate time delay. Clock frequency = 12 MHz, 12 oscillator clock. Pulse width = 50 millisecond.
Example – 8051 with clock frequency = 18 MHza. Generate a square wave of frequency 2 KHz
on pin P1.0 using mode 2.b. Calculate the smallest frequency possible
without using software counter. Clock frequency = 18 MHz Clock period = 1/18 µ sec. 1 m/c cycle = 12/18 µ sec = 2/3 µ sec.
2 KHz square wave clock period = ½ 10-3 sec. = 0.5 millisecond
Up time = 0.25 msDn time = 0.25 ms
Up time = 0.25 ms = 0.25 x 103 µ secNo. of m/c cycles in up time = (¼ x 103)/(2/3)
= ¼ x 103 x 3/2 = 3/8 x 103
= 3000/8 = (30 x 25)/2= 15 x 25 = 375
<- - - - - - 0.5 ms - - - - ->
- Delay of 375 m/c cycle can be achieved in many ways.375/3 = 125 – Generate delay of 125 m/c cycle 3 times375/5 = 75 – Generate delay of 75 m/c cycle 5 times375/15 = 25 – Generate delay of 25 m/c cycle 15 times: ::We can take any of the options. Let us take 1st one.
To generate delay of 125 m/c cyclePreset = (FFH) 255 – 125 = 130
Accounting for additional m/c cyclePreset = 131 = 83H
b. – Frequency is smallest when clock period = maximum
i.e. Up time and Down time = maximumi.e. Delay is maximum.
Delay is maximum when preset value =0i.e. No. of m/c cycles in Up time = FF+1
No. of m/c cycles in Dn time = FF+1Up time = 256 x 2/3 µ sec = 512/3 ≈ 170 µ secClock period = 341 µ sec.Frequency = 1/341 MHz = 1000/341 KHz
= 2.92 KHz
Example – Counter Operation- Design a counter to count pulses input at P3.4.- Determine the no. of pulses received in 1 minute.- 8051 is 12 MHz, 12 Clock m/c cycle.-> P3.4 pin is T0 i.e. -> external input to Timer 0
Let us calculate the maximum no. of pulses that can be counted.
- In 16 bit operation i.e. Mode 01 – (FFFF+1) = 65535 + 1 = 65536
- In 13 bit operation i.e. Mode 00 – 1FFF+1 = 8191 = 8192
- In 8 bit operation i.e. Mode 02 & Mode 03 – FF+1 = 255+1 = 256
Let us assume that 1 pulse corresponds to – one rotation of is wheel – circumference of wheel = 1 meter
Max. distance travelled in 1 minute can be measured as 8 bit operation – 256 meter.13 bit operation – 8192 meter16 bit operation – 65536 meter.Considering that overflow takes place in 1 minute duration
Max. distance travelled in 1 hour that can be measured with be 8 bit operation – 256 x 60 = 14760 meter
= 14.76 KMPH13 bit operation – 8192 x 60
= 491520 = 491.52 KMPH16 bit operation – 65536 x 60 = 3932160 meter.
= 3932.16 KMPH
For measuring automobile speed – 13 bit or 16 bit operation will be o.k.
- Delay operation can also be managed using hardware timer so that micro controller is free for carrying out other tasks.
Let us assume that Timer 1 is used for incorporating 1 minute delay12 MHz clock1 m/c cycle = 1 µ sec1 second = 106 µ sec = 106 m/c cycle
= 220 m/c cycle = 24 x 216 m/c cycle.
Thus 0000 to FFFF+1, counter has to repeat 16 times for delay of 1 sec.
For 1 Minute delay 1 minute = 60 x 16 x216 – 1 second delay must be repeated in loop by 60 times
Now, TMOD will become
C/T = 0 for Timer 1 – Timer operationMOV TMOD, #05H will get modified to MOV TMOD, #15H
0 0 0 1 0 1 0 1 = 15 H
DELIM SubroutineDELIM: MOV R3, #3CH ; for 60 secondsLOOP1: MOV R4, #10H ; for 16 times