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I/O devices (Peripherals)
Examples: switches, LED, LCD, printers,
keyboard, keypad
Interface chips
are needed to resolve the speed problem
synchronizes data transfer between CPU and I/O
device
Connection of Interface and CPU
Data pins are connected to CPU data bus
I/O port pins are connected to I/O device
CPU may be connected to multiple interface
IO ports are simplest interface
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-2
I/O Interfacing
Dedicated instructions for IO operations
(Isolated I/O)
same instruction for memory and IO
(memory-mapped I/O)
MCS-51 (8051) is memory mapped
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-3
Synchronization of CPU
and interface chip
To make sure that there are valid data in the
interface
two ways
Polling method: Read status bit - Simple method
Interrupt driven method: interface interrupts
the CPU when it has new data - CPU executes the
ISR
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-4
Synchronization of CPU
and interface chip
 Output synchronization: two ways of doing this
1. Polling method
 interface chip uses a status bit to indicate that the data
register is empty
 CPU keeps checking status bit until it is set, and then writes
data into interface chip
2. Interrupt driven method: interface chip interrupts
the CPU when it data register is empty. CPU executes
the ISR
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-5
Synchronization of CPU
and interface chip
 Methods used to synchronize data transfer between interface
chip and I/O devices:
1. Brute force method: interface chip returns voltage levels in its
input ports to CPU and makes data written by CPU directly
available on its output ports
 All 8051 port can perform brute force I/O
2. Strobe method:
 During input, the I/O device activates a strobe signal when data are
stable. Interface chip latches the data
 For output, interface chip places output data on output port. when
data is stable, it activates a strobe signal. I/O device latches the
data
3. Handshake method: two handshake signals are needed
 One is asserted by interface chip and the other by I/O device
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-6
8051 - Switch On I/O Ports
 Case-1:
 Gives a logic 0 on switch close
 Current is 0.5ma on switch close
 Case-2:
 Gives a logic 1 on switch close
 High current on switch close
 Case-3:
 Can damage port if 0 is output
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-7
Simple input devices
 DIP switches usually have 8 switches
 Use the case-1 from previous page
 Sequence of instructions to read is:
MOV
P1,#FFH
MOV
A,P1,
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-8
Bouncing contacts
Contact:
Push-button switches
Toggle switches
Electromechanical relays
Make and break Contact normally open switch
The effect is called "contact bounce" or, in a
switch, "switch bounce”.
If used as edge-triggered input (as INT0),
several interrupt is accorded
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-9
Hardware Solution
 An RC time constant to suppress the bounce
 The time constant has to be larger than the switch bounce
Vcc
OUT
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-10
Hardware Solution
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-11
Software Solution
Read the new state of switch N time
Wait-and-see technique
When the input drops
an “appropriate” delay is executed (10 ms)
then the value of the line is checked again to make
sure the line has stopped bouncing
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-12
Interfacing a Keypad
16 keys arranged as a 4X4 matrix
 Place a 0 on R0 port
 Read C port
 If there is a 0 bit
then the button
at the column/row
intersection has
been pressed.
 Otherwise, try next row
 Repeat constantly
hsabaghianb @ kashanu.ac.ir
F
E
D
C
B
A
9
8
7
6
5
4
3
2
1
R1
R2
R3
R4
0
C1
C2
C3
C4
Microprocessors 6-13
Interfacing a Keypad
scan:
scan1:
scan2:
scan3:
scan4:
mov
jnb
jnb
jnb
jnb
mov
jnb
P1,#EFH
P1.0,db_0
P1.1,db_1
P1.2,db_2
P1.3,db_3
P1,#DFH
P1.0,db_4
…..
…..
…..
F
E
D
B
A
9
8
7
6
5
4
3
2
8051
C
1
P1.7
P1.6
P1.5
P1.4
0
P1.3
P1.2
P1.1
P1.0
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-14
Interfacing a Keypad
db_0:
db_1:
lcall
jb
mov
ljmp
lcall
jb
mov
ljmp
wt_10ms
P1.0, scan1
A, #0
get_code
wt_10ms
P1.1, scan2
A, #1
get_code
mov
movc
ljmp
db
END
DPTR, #key_tab
A, @A+DPTR
scan
‘0123456789ABCDEF’
…..
…
…..
get_code:
key_tab:
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-15
Simple output devices
 Case-1
 LED is ON if output=zero
 Most LEDs drop 1.7 volts and need about 10ma
 Current is (5-1.7)/470
 Case-2
 Too much current
 Failure of Port or LED
 Case-3
 Not enough drive (1ma)
 LED is too dim
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-16
The 7-Segment Display
7 LEDs arranged to form the number 8.
By turning on and off (LEDs), different
combinations can be produced.
 useful for displaying the digits 0 through 9, and
some characters.
a
f
b
g
e
c
d
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-17
The 7-segment Display (Cont.)
7-segment displays come in 2 configurations:
Common Anode
Connect cathode to the output
Common Cathode
Connect cathode to the output
Therefore, the common anode variety would
be better for our interfacing needs.
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-18
Interfacing a 7-segment display
 A resistor will be needed to control the current
 This leaves two possibilities:
 Case 2 would be more appropriate
 Case 1 will produce different brightness depending on the
number of LEDs turned on.
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-19
Use of current buffer
 Interfacing to a DIP switch and 7-segment display
 Output a ‘1’ to ON a segment
 We can use 74244 to common cathode 7_seg
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-20
BCD to 7_Seg lookup table
mov
anl
mov
movc
mov
get_code:
7s_tab:
db
db
END
f
b
f
e
c
e
d
3fh,30h,5bh,4fh,66h
6dh,7dh,07h,7fh,6fh
a
a
g
a,p3
a,0fh
DPTR, #7s_tab
A, @A+DPRT
p1,a
a
b
g
e
a
b
c
d
hsabaghianb @ kashanu.ac.ir
d
f
g
b
f
f
c
d
pgfedcba
7_seg
he
x
0000
001111 11
3f
0001
00110000
30
0010
0101101 1
5b
0011
010011 11
4f
0100
011001 10
66
0101
01101101
6d
0110
01111101
7d
0111
00000111
07
1000
01111111
7f
1001
01101111
6f
a
g
c
BCD
a
g
e
c
d
a
b
f
c
e
g
a
b
f
g
c
d
b
c
d
Microprocessors 6-21
LCD Interfacing
 Liquid Crystal Displays (LCDs)
 cheap and easy way to display text
 Various configurations (1 line by 20 X char up to 8 lines X 80)
 Integrated controller
 The display has two register
 command register
 data register
 By RS you can select register
 Data lines (DB7-DB0) used to transfer data and commands
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-22
Alphanumeric LCD Interfacing
Microcontrolle
r
 Pinout
 8 data pins D7:D0
 RS: Data or Command
Register Select
 R/W: Read or Write
 E: Enable (Latch data)
E
R/W
RS
DB7–DB0
8
LCD
controller
 RS – Register Select
 RS = 0  Command Register
 RS = 1  Data Register
 R/W = 0  Write ,
 E – Enable
communications
bus
LCD Module
R/W = 1  Read
 Used to latch the data present on the data pins.
 D0 – D7
 Bi-directional data/command pins.
 Alphanumeric characters are sent in ASCII format.
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-23
LCD Commands
 The LCD’s internal controller can accept several
commands and modify the display accordingly.
Such as:
 Clear screen
 Return home
 Decrement/Increment cursor
 After writing to the LCD, it takes some time for it to
complete its internal operations. During this time, it
will not accept any new commands or data.
 We need to insert time delay between any two commands or
data sent to LCD
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-24
Pin Description
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-25
Command
Codes
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-26
LCD Addressing
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-27
LCD Timing
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-28
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-29
Interfacing LCD with 8051
8051
LM015
P3.4
RW
P3.5
E
P3.3
RS
P1.7-P1.0
hsabaghianb @ kashanu.ac.ir
D7-D0
Microprocessors 6-30
mov A, command
call cmd
delay
mov A, another_cmd
call cmd
delay
mov A, #’A’
call data
delay
mov A, #’B’
call data
delay
….
Command and Data Write Routines
data:mov P1, A
;A is ascii data
setb P3.3
;RS=1 data
clr P3.4
;RW=0 for write
setb P3.5
;H->L pulse on E
clr P3.5
ret
cmd:mov P1,A
;A has the cmd word
clr P3.3
;RS=0 for cmd
clr P3.4
;RW=0 for write
setb P3.5
;H->L pulse on E
clr P3.5
ret
Interfacing LCD
with 8051
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-31
Example
hsabaghianb @ kashanu.ac.ir
Microprocessors 6-32
8255 Usage: Simple Example
 8255 memory mapped to 8051 at address C000H base
 A = C000H, B = C001H, C = C002H, CR = C003H
 Control word for all ports as outputs in mode0
 CR : 1000 0000b = 80H
test:
mov
mov
movx
mov
A, #80H
DPTR, #C003H
@DPTR, A
A, #55h
repeat:mov
DPTR,#C000H
movx
@DPTR, A
inc
DPTR
movx
@DPTR, A
inc
DPTR
movx
@DPTR, A
cpl
A
acall MY_DELAY
sjmp
repeat
hsabaghianb @ kashanu.ac.ir
;
;
;
;
;
;
;
;
;
;
;
;
;
;
control word
address of CR
write control word
will try to write 55 and AA
alternatively
address of PA
write 55H to PA
now DPTR points to PB
write 55H to PB
now DPTR points to PC
write 55H to PC
toggle A (55AA, AA55)
small delay subroutine
for (1)
Microprocessors 6-33