Agenda

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Agenda

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Agenda 1. Overview of 8051 Architecture, Timing, On-chip Resources, Instruction Set etc. Derivative products 2. Programming the 8051: Basic techniques, tips & tricks. – PowerPoint PPT presentation

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Title: Agenda

1
Agenda

1. Overview of 8051 Architecture, Timing, On-chip
Resources, Instruction Set etc. Derivative
products
2. Programming the 8051 Basic techniques, tips
tricks.
3. Development Support Development Boards,
Emulators, EPROM Programmers, Compilers, etc.
4. I2C, a simple Multi-master 2-wire serial bus.
5. ACCESS.Bus, an I2C-based protocol for
connecting peripherals to workstations/PCs.

2
The 8051

An 8-bit Microcontroller optimized for control
applications.
A Microcontroller derivative family based on the
8051 core.
A Microcontroller because you can make a one-chip
system with the one chip containing
Program Data Memory
I/O Ports
Serial Communication
Counters/Timers
Interrupt Control logic
A-to-D and D-to-A convertors
so on ...

3
Features of the 8051

- 8 Bit data path and ALU.
- Easy interfacing.
- 12 to 30 MHz versions available.
( 1 µsec to 400 ns for single cycle
instructions).
- Full instruction set including
Multiply and Divide.
Bit set, reset, and test (Boolean instructions).
- Variety of addressing modes.

4
Features of the 8051 (cont'd)

- 4K X 8 ROM - Program memory.
- 128 x 8 RAM - Data memory.
- Special function registers.
- Serial I/O port.
- 32 I/O lines.
- Two 16-bit counter/timers.

5
8051 Logic Symbol
6
80C51 Block Diagram
External Interrupts
Timer 1
4k byte ROM
Counter Inputs
128 byte RAM
Interrupt Control
Timer 0
CPU
Serial Port
Bus Control
I/O Ports
OSC
TXD
RXD
P0
P3
P1
P2
(Address/Data)
7
Addressing Space

- 64K X 8 ROM - Program memory.
- 64K x 8 RAM - External data memory.
- 256 x 8 RAM - Internal data memory.
- 128 x 8 Special function registers (SFRs).
- Bit addressing of 16 RAM locations
and 16 SFRs.

8
Program Memory

- 16 bit Program Counter (PC).
- 16 bit Data Pointer (DPTR).
- 64K byte address space each for Program Data.
- Table lookup using relative addressing
PC ACC (Move).
DPTR ACC (Move and jump).
- EA pin disables internal ROM and
activates external program memory
and addressing.

9
Internal Data Memory

- 128 bytes of RAM.
- Directly addressable range
00 to 7F hexadecimal.
- Indirectly addressable range
00 to FF hexadecimal.
- Bit addressable space
20 to 2F hexadecimal .
- Four register banks
00 to 1F hexadecimal.

10
Internal Data Memory
END 8051 RAM

7F
30
FF . . . . . . . . . F8
2F
BIT ADDRESSABLE
07 . . . . . . . . . 00
20
1F
REGISTER BANK 3
20
17
REGISTER BANK 2
18
0F
REGISTER BANK 1
08
R7
07
R6
R5
R4
REGISTER BANK 0
R3
R2
R1
00
R0
11
External Data Memory

- 64K byte address space.
- Indirectly addressable via R0 and R1
in 256 byte segments.
- Entire space is indirectly addressable
via the data pointer DPTR.

12
External Bus Expansion
8051
A15 - A8 High byte of address

PORT 2
PORT 0
ALE
P3.7
P3.6
PSEN

AD7 - AD0 Data and low byte address
ALE Address latch enable
RD Read strobe
WR Write strobe
PSEN Program store enable
13
8051 Timing
State 1
State 2
State 3
State 4
State 5
State 6
State 1
State 2
P1
P2
P1
P2
P1
P2
P1
P2
P1
P2
P1
P2
P1
P2
P1
P2
XTAL2
ALE
_____ PSEN
P0
PCL out
PCL out
PCL out
Data sampled
Data sampled
Data sampled
PCH out
PCH out
P2
14
External Program Memory
8051
A15 - A8
PORT2
ROM(S)
ALE
ADDRESS LATCH
ADDRESS INPUTS
AD7 - AD0
PORT0
A7 - A0
DATA OUTPUTS
D7 - D0
PSEN
OE
15
External Data Memory

64K byte adress space.
Indirectly addressable via R0 and R1
in 256 byte segments.
Entire space in indirectly addressable
via the data pointer DPTR.

RAM(S) or I/O
8051
DECODE
CE
PORT 2
ALE
ADDRESS INPUTS
ADDRESS LATCH
PORT 0
DATA OUTPUTS
R/W
WR
OE
RD
16
Reset

RST pin is Schmitt trigger input.
External reset is asychronous to the internal
clock.
RST pin must be high for at least two machine
cycles while the oscillator is running.
Internal RAM not affected by reset, but
indeterminate on power up.
Port pins in random state until oscillator
starts and algorithm write 1's to them.
Reset sets PC to 0000.
Typical circuits

5V
5V
8051
80C51
10uF
2.2uF
RST
RST
8.2K
17
Special Function Register Space

- 128 byte address space, directly
addressable as 80 to FF hex.
- 16 addresses are bit addressable
Set, Clear, AND, OR, MOV
(those ending in 0 or 8).
- This space contains
Special purpose CPU registers.
I/O control registers.
I/O ports.

18
Special Function Register Map
Bit Addressable

F8
F0 B
E8
E0 ACC
D8
D0 PSW
C8
C0
B8 IP
B0 P3
A8 IE
A0 P2
98 SCON SBUF
90 P1
88 TCON TMOD TL0 TL1 TH0 TH1
80 P0 SP DPH DPL PCON

19
Special Function Registers

CPU registers
- ACC Accumulator.
- B B register.
- PSW Program Status Word.
- SP Stack Pointer.
- DPTR Data Pointer (DPH, DPL).
Interrupt control
-IE Interrupt Enable.
-IP Interrupt Priority.
I/O Ports
- P0 Port 0.
- P1 Port 1.
- P2 Port 2.
- P3 Port 3.

20
Special Function Registers (cont'd)

TImers
- TMOD Timer mode.
- TCON Timer control.
- TH0 Timer 0 high byte.
- TL0 Timer 0 low byte.
- TH1 Timer 1 high byte.
- TL1 Timer 1 low byte.
Serial I/O
- SCON Serial port control.
- SBUF Serial data registers.
Other
- PCON Power control misc.

21
PSW Program Status Word

CY AC F0 RS1 RS0
OV ---- P
- CY Carry Flag.
- AC Auxiliary Carry Flag.
- F0 Flag 0 (available for user).
- RS1 Register Select 1.
- RS0 Register Select 0.
- OV Arithmetic Overflow Flag.
- P Accumulator Parity Flag.

RS1 RSO Register
Bank Address 0 0 0 00h - 07h 0 1 1 08h -
0Fh 1 0 2 10h - 17h 1 1 3 18h - 1Fh
22
I/O Ports

- Four 8-bit I/O ports.
- Most have alternate functions.
- Quasi-bidirectional
Soft pull-up when port latch
contains a 1. Can be used as
inputs (30Kohm average pullup).
Strong pull-up for 2 CPU cycles
during 0 to 1 transitions.

23
Port Configuration
24
Port 0

- As an I/O port
No strong pull-up, outputs act as
open drain.
- As a multiplexed data bus
Tristate bus with strong pull-ups.
8-bit instruction bus, strobed by PSEN.
Low byte of address bus, strobed by ALE.
8-bit data bus, strobed by WR and RD.
- 3.2 mA outputs (about 8 LSTTL loads).

25
Port 1

As an I/O port
Standard quasi-bidirectional.
- Alternate functions
Only on some derivatives.
- 1.6 mA outputs (about 4 LSTTL loads).

26
Port 2

- As an I/O port
Standard quasi-bidirectional.
- Alternate functions
High byte of address bus for external
program and data memory accesses.
- 1.6 mA outputs (about 4 LSTTL loads).

27
Port 3

- As an I/O port
Standard quasi-bidirectional.
- Alternate functions
Serial I/O - TXD, RXD
Timer clocks - T0, T1
Interrupts - INT0, INT1
Data memory - RD, WR
- 1.6 mA outputs (about 4 LSTTL loads).

28
Counter / Timers

- Two 16-bit Counter/Timers
Up counters, can interrupt on overflow.
- Counts
CPU cycles (crystal/12).
External input (max. half CPU rate).
- Four Operation Modes.

29
Timer Modes

- Timer Mode 0
Emulates 8048 counter/timer (13-bits).
8-bit counter (TL0 or TL1).
5-bit prescaler (TH0 or TH1).
- Timer Mode 1
Simple 16-bit counter.
- Timer Mode 2
8-bit auto-reload.
Counter in TL0 or TL1.
Reload value in TH0 or TH1.
Provides a periodic flag or interrupt.

30
Timer Modes (cont'd)

- Timer Mode 3
Splits timer 0 into two 8-bit counter/timers.
First counter (TLO) acts like mode 0,
without prescaler.
Second counter (TH0)
Counts CPU cycles.
Uses TR1 (timer 1 run bit) as enable.
Uses TF1 (timer 1 overflow bit) as flag.
Uses Timer 1 interrupt.
Timer 1 (when timer 0 is in mode 3 )
Counter stopped if in mode 3.
Running in mode 0, 1, or 2.
Has gate (INT1) and external input (T1),
but no flag or interrupt.
May be used as a baud rate generator.

31
Counter/Timer in 16-bit (Mode 1)
The Gate input controls whether the Counter runs
while gated by the interrupt signal or not.
32
TMOD Counter/Timer Mode Register
GATE C/T M1 M0 GATE C/T M1 M0 Timer 1 Timer 0

- GATE Permits INTx pin to enable/disable
counter.
- C/T Set for counter operation, reset for
timer operation.
- M1, M0
00 Emulate 8048 counter/timer (13-bits).
01 16-bit counter/timer.
10 8-bit auto-reload mode
11 Timer 0 two 8-bit timers.
Timer 1 Counting disabled. Timing function
allowed. Can be used as Baud Rate generator.

33
TCON Counter/Timer Control Register
TF1 TR1 TF0 TR0 IE1 IT1 IE0 IT0

- TF1, TF0 Overflow flags for Timer 1 and Timer
0.
- TR1, TR0 Run control bits for Timer 1 and
Timer 0. Set to run, reset to hold.
- IE1, IE0 Edge flag for external interrupts 1
and 0.
Set by interrupt edge, cleared when interrupt is
processed.
- IT1, IT0 Type bit for external interrupts.
Set for falling edge interrupts, reset for 0
level interrupts.
not related to counter/timer operation.

34
Serial Interface

- Full duplex UART.
- Four modes of operation
Synchronous serial I/O expansion.
Asynchronous serial I/O with variable
baud rate.
Nine bit mode with variable baud rate.
Nine bit mode with fixed baud rate.
- 10 or 11 bit frames.
- Interrupt driven or polled operation.
- Registers
SCON - Serial port control register.
SBUF - Read received data.
- Write data to be transmitted.
PCON - SMOD bit.

35
Serial Interface Modes of Operation

TXD and RXD are the serial output and input pins
(Port 3, bits 1 and 0).
Mode 0 Shift Register Mode. Serial data is
transmitted/received on RXD. TXD outputs shift
clock. Baud
Rate is 1/12 of clock frequency.
Mode 1 10-bits transmitted or received. Start
(0), 8 data bits (LSB first), and a stop bit (1).
Baud Rate Clock is variable using Timer 1
overflow or external count input. Can go up to
104.2KHz (20MHz osc.).
Mode 2 11-bits transmitted or received. Start
(0), 8 data bits (LSB first), programmable 9th
bit, and stop bit (1). Baud Rate programmable to
either 1/32 or 1/64 oscillator frequency (625KHz
for 20MHz osc.).
Mode 3 11-bit mode. Baud Rate variable using
Timer 1 overflow or external input. 104.2 KHz
max. (20 MHz osc.).

36
Multi-Drop Communication

Serial Communication Modes 2 and 3 allow one
"Master" 8051 to control several "Slaves"
The serial port can be programmed to generate an
interrupt if the 9th data bit 1.
The TXD outputs of the slaves are tied together
and to the RXD input of the master. The RXD
inputs of the slaves are tied together and to the
TXD ouput of the master.
Each slave is assigned an address. Address bytes
transmitted by the master have the 9th bit 1.
When the master transmits an address byte, all
the slaves are interrupted. The slaves then check
to see if they are being addressed or not.
The Addressed slave can then carry out the
master's commands.

37
SCON Serial Control Register
SMO SM1 SM2 REN TB8 RB8 TI RI

- SM0, SM1 Serial Mode
00 Mode 0 Shift register I/O expansion.
01 Mode 1 8-bit UART with variable baud
rate.
10 Mode 2 9-bit UART with fixed baud rate.
11 Mode 3 9-bit UART with variable baud
rate.
- SM2
Mode 0 Not used.
Mode 1 1 Ignore bytes with no stop bit.
Mode 2,3 0 Set receive interrupt (RI) on all
bytes.
1 Set RI on bytes where bit 9 1.
- REN Enables receiver.
- TB8 Ninth bit transmitted (in modes 2 and 3).
- RB8 Ninth bit received
Mode 0 Not used.
Mode 1 Stop bit.
Mode 2,3 Ninth data bit.
- TI Transmit interrupt flag.
- RI Receive interrupt flag.

38
Interrupt System

- 5 Interrupt Sources (in order of priority)
External Interrupt 0.
Timer 0.
External Interrupt 1.
Timer 1.
Serial Port.
- Each interrupt type has a separate
vector address.
- Each interrupt type can be programmed
to one of two priority levels.
- External interrupts can be programmed
for edge or level sensitivity.

39
IE Interrupt Enable Register
EA ---- ---- ES ET1 EX1 ET0 EX0

- EA Global interrupt enable.
- ES Serial interface.
- ET1 Timer 1.
- EX1 External interrupt 1.
- ET0 Timer 0.
- EX0 External interrupt 0.
- 0 Disabled.
- 1 Enabled.

40
Interrupt Vector Addresses

Source Address
IE0 03H
TF0 0BH
IE1 13H
TF1 1BH
RITI 23H

The 8051 starts execution at 0000H after Reset.
41
IP Interrupt Priority Register
----- ----- ----- PS PT1 PX1 PT0 PX0

- PS Serial interface.
- PT1 Timer 1.
- PX1 External interrupt 1.
- PT0 Timer 0.
- PX0 External interrupt 0.
- 0 Low priority.
- 1 High priority.

42
80C51(CMOS) vs. 8051(NMOS)

Controlled Power Reduction
Idle State
Power down state
Power savings in CMOS ports
General purpose software flags
Higher speed versions in 80C51 (up to 30MHz)
Static versions in development

43
PCON Power Control Register
SMOD ---- ---- ---- GF1 GF0 PD IDL

- POWER DOWN OPERATION
Setting PD bit stops oscillator.
RAM contents are saved.
Exit via Reset.
Some (newer) 80C51 derivatives allow Power-Down
wakeup via Interrupt.

44
PCON Power Control Register

- IDLE MODE OPERATION
Setting IDL gates clocks off, leaves oscillator
running.
All register and RAM contents are saved.
Interrupt sources remain active
Serial interface.
External interrupts.
Timers.
Exit with any enabled interrupt or Reset.
- GF0, GF1 are general purpose software flags.
- SMOD serial interface control bit.
Doubles baud rate in modes 1,2, and 3.
- Only SMOD available on NMOS parts.

45
Power Consumption

Example for 80C51 at Vcc 5V.
Mode / Freq. 0.5 MHz 16 MHz
Operating 2.2 mA 20.5 mA
Idle 0.9 mA 5.0 mA
Power Down 50 uA 50 uA

46
8051 Addressing Modes

There are basically 5 ways of specifying
source/destination operand addresses
1. Particular On-chip Resources
This includes the Accumulator (A), the Stack
Pointer (SP), the Data Pointer (DP), the Program
Counter (PC), and the Carry (C). Other On-chip
Registers are Memory-mapped while these have
special Op-codes.
2. Immediate operands
The sign is the designator. These are 8-bits
except for DPTR contents (16-bits).
3. Register operands
Designated as Rn, where n is 0..7. One of the
four Register Banks is used (PSW selected).
4. Direct Operands
From 00 to FF Hex, specifies one of the internal
data addresses.
5. Indirect Address
Designated as _at_Ri, where i is 0 or 1, uses the
contents of R0 or R1 in the selected Register
Bank to specify the address. Other form is _at_A,
using Accumulator contents.

47
Instruction Set Arithmetic

Mnemonics Operands Bytes/Cycles
ADD A, Rn 1/1
ADDC A, direct 2/1
SUBB A, _at_Ri 1/1
A, data 2/1
INC A 1/1
DEC Rn 1/1
direct 2/1
_at_Ri 1/1
INC DPTR 1/2
MUL AB 1/4
DIV AB 1/4
DA A 1/1

48
Instruction Set Logic

Mnemonic Operands Bytes/Cycles
ANL A, Rn 1/1
ORL A, direct 2/1
XRL A, _at_Ri 1/1
A, data 2/1
direct, A 2/1
direct, data 3/2
C, bit 2/2
C, /bit 2/2
CLR A 1/1
CPL C 1/1
bit 2/1

49
Instruction Set Logic (cont'd)

Mnemonic Operands Bytes/Cycles
RL A 1/1
RLC A 1/1
RR A 1/1
RRC A 1/1
SWAP A 1/1
SETB C 1/1
CLR bit
CPL
2/1

50
Instruction Set Data Transfer

Mnemonic Operands Bytes/Cycles
MOV A, Rn 1/1
A, direct 2/1
A, _at_Ri 1/1
A, data 2/1
Rn, A 1/1
Rn , direct 2/2
Rn, data 2/1
direct, A 2/1
direct, Rn 2/2
direct, direct 3/2
direct, _at_Ri 2/2
direct, data 3/2

51
Instruction Set Data Transfer (cont'd)

Mnemonic Operands Bytes/Cycles
MOV _at_Ri, A 1/1
_at_Ri, direct 2/2
_at_Ri, data 2/1
DPTR, data16 3/2
C, bit 2/1
bit, C 2/2
MOVX A,_at_DPTR 1/2
_at_DPTR,A 1/2
A,_at_Ri 1/2
_at_Ri,A 1/2

52
Instruction Set Data Transfer (cont'd)

Mnemonic Operands Bytes/Cycles
MOVC A, _at_ADPTR 1/2
A, _at_APC 1/2
PUSH direct 2/2
POP direct 2/2
XCH A, Rn 1/1
A, direct 2/1
A, _at_Ri 1/1
XCHD A, _at_Ri 1/1

53
Instruction Set Branching

Mnemonic Operands Bytes/Cycles
LCALL addr16 3/2
ACALL addr11 2/2
RET - 1/2
RETI - 1/2
LJMP addr16 3/2
AJMP addr11 2/2
SJMP rel 2/2
JMP _at_ADPTR 1/2
JZ rel 2/2
JNZ rel 2/2

54
Instruction Set Branching (cont'd)

Mnemonic Operands Bytes/Cycles
CJNE A, direct, rel 3/2
A, data, rel 3/2
Rn, data, rel 3/2
_at_Ri,data,rel 3/2
DJNZ Rn, rel 2/2
direct, rel 3/2
NOP - 1/1
JC rel 2/2
JNC rel 2/2
JB bit, rel 3/2
JNB bit, rel 3/2
JBC bit, rel 3/2

55
The I C BUS(Inter - Integrated Circuit)
2

A 2 wire serial data and control bus
Implemented with one serial data (SDA) and one
clock (SCL) line.
Unique start and stop conditions.
Slave selection protocol uses a 7-Bit slave
address.
Bi-directional data transfer.
Acknowledgement after each byte transferred.
No limit on the number of bytes transferred.
Real multimaster capability.

56
I2C Bus Features

Clock synchronization.
Arbitration procedure.
Transmission speed up to 100Khz
Maximum bus length of 4 meters.
Maximum drive capacity of 400pF.
Allows series resistor for IC protection.
Compatible with most IC technologies (TTL,
CMOS,Etc.).

57
I2C Definitions

MASTER
Initiates a transfer by generating start and
stop conditions.
Generates the clock.
Transmits the slave address.
Determines data transfer direction.
SLAVE
Responds only when addressed.
Timing is controlled by the clock line.

58
I2C Hardware Details

Devices connected to the bus must have an open
drain or open collector output for serial clock
and data.
The device must also be able to sense the logic
level on these pins.
All devices must have a common reference
ground.
The serial clock and data lines are connected
to VCC through pull up resistors.
At any given moment the I2C bus is
Idle,
in Master transmit mode,
or in Master receive mode.

59
The Open Drain Configurationof I2C Circuits
VDD
Pull-up Resistors
Rp
Rp
Serial data line
SDA
Serial clock line
SCL
SCLK1 OUT
SCLK2 OUT
DATA1 OUT
DATA2 OUT
SCLK IN
SCLK IN
DATA IN
DATA IN
DEVICE 2
DEVICE 1
I2C devices are wire ANDed together.
60
Start and Stop Conditions

A transition of the data line, when the clock
line is high, is defined as either a start or a
stop condition.
Both start and stop conditions are generated by
bus master.
The Bus is busy after a start condition.

SDA
SDA
SCL
SCL
S
P
Stop Condition
Start Condition
61
Bit Transfer on the I2C Bus
In normal data transfer, the data line only
changes state when the clock is low.
SDA
SCL
Data line stable Data valid
Change of data allowed
62
I2C Address

Each node has a unique 7 bit address.
Peripherals usually have fixed and programmable
address portions.
Addresses starting with 0000 or 1111 have
special functions.
0000000 is a general call address.0 0000001
is a null address.
1111xxxx is reserved for future bus
expansion

63
First Byte Transmitted on the I2C Bus
LSB
ACK
MSB
R/W
7-bit slave address
R/W 0 - Slave will be written by master. 1 -
Slave will be read by master.
64
Acknowledgement

Master/slave receivers pull data line low for
one clock pulse after reception of a byte.
Master receiver leaves data line high after
receipt of the last byte requested.
Slave receiver leaves data line high on the
byte following the last byte it can accept.

65
Data Transfer on the I2C Bus
SDA
MSB
SCL
3 - 8
1
2
7
8
9
S
P
1
2
9
ACK
ACK
START CONDITION
STOP CONDITION
66
Possible Data Formats
Master Write

SLAVE ADDRESS W A DATA A DATA A P

Acknowledge from slave
Master Read

SLAVE ADDRESS R A DATA A DATA NA P

Acknowledge from master
Acknowledge from slave
No acknowledge from master
67
I2C Clock Synchronization

Clock synchronization is used to synchronize
arbitrating masters.
It can also be used as a handshake by a slave
device to slow data transfer from a master.
The clock synchronization procedure consists of
two algorithms
1) If the clockline goes low when a master is
asserting a high,
the master asserts a low and starts to time
out its low clock period.
2) When a master stops asserting a low on the
clock line, it waits
until the clockline actually goes high before
starting to time the
high period.

68
I2C-Bus Clock Synchronization Procedure
Start counting high period
Wait State
CLK 1
CLK 2
Start counting low period
SCL
69
Multimaster I2C Systems

Multimaster situations require two additional
features of the I2C protocol.
ARBITRATION
Arbitration is the procedure by which competing
masters decide final control of the bus.
I2C arbitration does not corrupt the data
transmitted by the prevailing master.
Arbitration is performed bit by bit until it is
uniquely resolved.
Arbitration is lost by a master when it
attempts to assert a high on the data line and
fails..

70
Arbitration Procedure Between Two Masters
Transmitter 1 loses arbitration
DATA1
DATA2
SDA
1
2
3
4
5
SCL
71
I2C Family ICs

Microcontrollers
Microprocessors
General Purpose Peripherals
I/O, Memory, Display, DAC, ADC,
Clock/Calendar
Peripherals for Specific Target Martkets
Audio, Telephony, Video

72
An OpenDesktop Bus Standardbased onI2C
73
ACCESS.bus .1

DEC has invented an interconnect method for
connecting a PC or Workstation to
low speed I/O devices such as
Keyboards
Mouses
Trackballs
Tablets
Low speed printers
Modems
This interconnect method, known as ACCESS.bus, is
based on the I2C serial protocol invented by
Philips.

74
ACCESS.bus .2

ACCESS.bus features
80 KBps Peak Bandwidth
Hot plugging and unplugging of devices
(keyboard, mouse, etc.)
Up to 14 devices
Up to 8 Meters (26.4 feet) in length
Serial, daisy-chained 4-pin cable (2 pins are
power and ground). Only ONE device port needed on
computer.

75
ACCESS Bus .3

ACCESS.Bus features
Layered 3-layer protocol defined by DEC
Physical layer is I2C.
Base Protocol over I2C defines the structure
of I2C messages and defines Control and Status
Messages. Also supports auto-addressing and hot
plugging.
Applications Protocol defines message
semantics for particular device types.
Extremely low cost implementation based on
off-the-shelf Microcontrollers with I2C such as
the Signetics 83/87C751 (used in new DEC
workstation ).

76
ACCESS.Bus .4

Device address and type recognition is
automatic. No drivers have to be loaded.
Concise protocol. Only 7 standard message
types. Fully implemented in the 87C751 with 2K of
Program memory.
ACCESS.Bus is part of DEC's ARC and ACE
platforms.
Fully open and free. No royalties.
DEC and Signetics will provide Developer's Kit
with all information required to to develop
applications.
DEC's TRI/ADD developer program will provide
technical support, documentation and updates,
technical seminars, and newsletters and assist
with marketing support.

77
ACCESS.bus .5

The closest thing to the ACCESS.bus is Apple's
ADB (Apple Desktop Bus). The following is a
comparison between ADB and ACCESS.bus
ADB ACCESS.bus
Hot-Plugging not recommended fully supported
Peak data rate 10 KBits/sec 80 KBits/sec
Daisy-chain limit 3 devices 14 devices
3rd party access Proprietary Open. No royalties
Max. cable length 5 meters 8 meters

78
Directions from the Core Product
Analog-to- Digital
Low Power Low Voltage
EPROM OTP
Very Small Packages
Extended I/O
Memory 2 to 32 K
80C51
EEPROM derivatives
ASIC Cell Library
I2C Serial Bus
Speed Up to 30 MHz
79
Philips/Signetics 8051 Family

Product Name Process ROM RAM Pins
8-bit Ports Serial I/O Timers Special
8031/51 NMOS 4K 128 40 4 UART 2 Industry Standard
8032/52 NMOS 8K 256 40 4 UART 3 Industry Standard
8XC751 CEPROM 2K 64 24 23/8 I2C 1 24 Pin Skinny
DIP
8XC752 CEPROM 2K 64 28 25/8 I2C 1 8-bit A/D,PWM
8XC31/51 CEPROM 4K 128 40 4 UART 2 20,24, 30MHz
8XCL410 SACMOS 4K 128 40 4 I2C 2 LowVolt/Power
(1.8 volts)
80/3C851 EEPROM 4K 128 40 4 UART 2 256 EEPROM
8XC550 CEPROM 4K 128 40 4 UART 2 8-bit A/D, WD
8XC451 CEPROM 4K 128 68 7 UART 2 7 I/O Ports
8XC652 CEPROM 8K 256 40 4 UART,I2C 2 8K ROM, I2C
Serial Bus
8XC52 CEPROM 8K 256 40 4 UART 3 Industry Standard
8XC053/054 CEPROM 8K/16k 192 42 4 -- 2 TV
Display (OSD), D/A
8XC562 CEPROM 8K 256 68 6 UART 4 8-bit A/D, PWM,
WD, T2
8XC552 CEPROM 8K 256 68 6 UART,I2C 4 10-bit A/D,
PWM, WD, T2
8XC654 CEPROM 16K 256 40 4 UART,I2C 2 16K ROM,
I2C Serial Bus
8XC524 CEPROM 16K 512 40 4 UART, I2C 3 16K, 512
bytes, WD
8XC528 CEPROM 32K 512 40 4 UART,I2C 3 32K ROM,
512 RAM, WD

80
80C51 CodingIdeas and Examples
81
Reading a Timer "on the Fly"

ReadTimer MOV ValH,TH0 Read initial timer high
and low values.
MOV ValL,TL0
MOV A,TH0 Read timer high byte again.
CJNE A,ValH,ChkHigh Has it changed?
SJMP RTEX If not, first sample is OK.
ChkHigh JB ValL.7,RTEX Otherwise, check low
byte to see if it
changed after the original high byte
sample.
MOV ValH,A If it did change, use second high
byte
sample.
RTEX RET

82
Compare

The 80C51 has no basic compare instruction.
However, the CJNE (compare and jump if not equal)
instruction leaves the carry flag set after
execution, allowing further magnitude comparisons
to be made.
This method works for all variations of CJNE
CJNE A,direct,rel
CJNE A,data,rel
CJNE Rn,data,rel
CJNE _at_Ri,data,rel

83
Compare

Examples of four variations of magnitude
comparison
CJNE A,Value,Test Branch if A lt Value.
Test JC LT
CJNE A,Value,Test Branch if A gt Value.
Test JNC GTE
CJNE A,Value,Test Branch if A gt Value.
SJMP Else
Test JNC GT
Else -----
CJNE A,Value,Test Branch if A lt Value.
SJMP LTE
Test JNC LTE

84
Read-Modify-Write

Most instructions that reference 80C51 port data
read the value on the port pins rather than the
value in the port latch. However, some
instructions read the port latch instead.
1) Arithmetic or logical operations that may
alter port values
ANL port,src
ORL port,src
XRL port,src
INC port
DEC port
DJNZ port,label
3) Instructions that may alter port bits
MOV bit,C
JBC bit,label
CPL bit
CLR bit
SETB bit

85
Single Step Under Program Control

The 80C51 does not have any specific built-in
facility for allowing a hardware single step
operation. However, when a Return from Interrupt
instruction is executed, at least one instruction
from the originally interrupted routine is always
executed before another interrupt may be
serviced.
Thus, if execution of RETIs are carefully
controlled while an interrupt is pending, a
software single step may be effected.

86
Single Step Under Program Control

This example uses external interrupt 0 as the
means to accomplish the single step. This
interrupt is a good choice because it is the
highest priority interrupt . Note the user
program must not write to the IE or IP registers
or make use of other interrupt related functions.
Set up for single step of some user routine
StartSS SETB PX0 Set INT0 as high priority.
SETB IT0 Set INT0 to edge triggered mode.
JNB INT0, Wait for a "single step" interrupt
to come,
JB INT0, and go.
MOV IE,81h Enable INT0 and insure that we are
not
LJMP UserProg interrupted during the
following jump.
ExInt0 . . Code to dump registers, user
program
. . address, etc.
JNB INT0, Wait for a "single step" interrupt
to come,
JB INT0, and go.
RETI This RETI will allow one user program
instruction to
execute, after which we will return to the
INT0 service
routine.

87
Pulse Width Measurement
Problem measure the width of an input pulse.
?
start timer
stop timer
Assumption use external interrupt 0 for the
pulse input. Use timer 0 in gated mode.
Note to measure pulse low time in this manner,
the input must be inverted externally.
88
Pulse Width Measurement

Setup MOV TMOD,09h Timer 0 gate on, in mode 1.
MOV TCON,01h Set INT0 to edge triggered mode.
MOV TH0,0 Clear timer 0 for measurement.
MOV TL0,0
SETB TR0 Start timer in gated mode.
SETB EX0 Enable external interrupt 0.
SETB EA Enable global interrupts.
. .
. .
. .
External interrupt 0 service routine.
ExInt0 CLR TR0 Stop timer.
MOV ValH,TH0 Save timer value.
MOV ValL,TL0
MOV TH0,0 Clear timer 0 for measurement.
MOV TL0,0
SETB TR0 Restart timer.
RETI

89
Pulse Period Measurement
Problem measure the period of an input pulse.
?
start timer
stop timer
Assumption use external interrupt 0 for the
pulse input.
Note this method may entail some loss of
precision due to the possibility of variable
interrupt latency.
90
Pulse Period Measurement

Setup (same as previous example, but leave timer
gate function turned off)
MOV TMOD,01h Timer 0 in mode 1.
External interrupt 0 service routine.
ExInt0 CPL TR0 Complement the timer run flag.
This starts
and stops the timer on alternate
interrupts.
JB TR0,INT0EX Exit if timer is running.
MOV ValH,TH0 Otherwise sample the timer value.
MOV ValL,TL0
MOV TH0,0 Clear timer so another sample can
MOV TL0,0 be taken.
INT0EX RETI

91
Creating an Output Pulse
Problem create a pulse of known duration on a
port pin.
timer
stop pulse
start pulse, timer
Note the precision of pulses generated using
this method will vary depending on the interrupt
latency of the timer interrupt.
Assumption use any spare port bit for the output.
92
Creating an Output Pulse

Setup MOV TCON,0h Make sure timer is stopped.
MOV TMOD,01h Set timer to mode 1.
MOV TH0,HiTime Load timer with pulse duration.
The value is the MOV TL0,LoTime two's
complement of the number of machine cycles
to use for the pulse width.
SETB TR0 Start timer.
SETB P2.0 Start pulse (use CLR for a low going
pulse).
Tiimer 0 interrupt routine.
T0INT CLR P2.0 End of pulse (use SETB for a low
going pulse).
CLR TR0 Stop timer.
RETI

93
Programming a PWM Output
Problem create a PWM output on a port pin.
set timer high time
set timer low time
repeat
Note the precision of pulses generated using
this method will vary depending on the interrupt
latency of the timer interrupt.
94
Programming a PWM Output

T0INT CLR TR0 Stop timer.
CPL P2.0 Toggle output bit.
JB P2.0,SetPWMHigh Is current phase high or
low?
MOV TH0,PWMLowH Set PWM low time.
MOV TL0,PWMLowL
SJMP T0EX
SetPWMHigh MOV TH0,PWMHighH Set PWM high time.
MOV TL0,PWMHighL
T0EX SETB TR0 Restart timer.
RETI

Note for higher frequency pulses, it may be
possible to use the timer reload feature (mode 2)
to obtain more accurate pulse durations.
95
Block Memory Move with External Data Memory
FFFF
Problem move any random external data memory
block of any length to another location.

0000
96
Block Memory Move

BlockMove MOV R0,LOW(FromAddr) Initialize
'from' memory pointer.
MOV P2,HIGH(FromAddr)
MOV DPTR,ToAddr Initialize 'to' memory
pointer.
MOV R1,LOW(ByteCount) Initialize byte count.
MOV R2,HIGH(ByteCount)
Loop MOVX A,_at_R0 Read in a source block byte.
MOVX _at_DPTR,A Write byte out to destination
block.
INC DPTR Increment 'to' memory pointer.
INC R0 Increment 'from' memory pointer.
MOV A,R0
JNZ L1
INC P2
L1 DJNZ R1,Loop Decrement byte count and
DJNZ R2,Loop test for end of block.
RET

97
Implementing a Second UART in Firmware

Often, an application may require a second UART
communication function. A simplex (transmit or
receive only at any one time) UART can be
programmed with the use of one timer.
The transmit routine will simply start the timer,
create a start bit, and then send one bit at
every timer interrupt, until finally sending the
stop bit. The transmit bit may be any unused port
bit.
Since the receive routine must sample each bit
somewhere in the middle of the bit cell, it
starts the timer with a value of a half bit cell
when a start is detected. Then, on the first
timer interrupt, it verifies the presence of the
start bit and changes the timer count to one full
bit cell. On every subsequent timer interrupt,
one data bit is read, until finally the stop bit
is verified. The receive bit must be an external
interrupt pin (usually INT0 or INT1).

98
UART Flow Start Transmit
Start Transmit
Set up timer for one bit cell time.
Get byte to be transmitted and set bit count.
Send start bit.
Exit
99
UART Flow Start Receive
Start Receive (START bit Interrupt)
Set bit count.
Set up timer for one half bit cell time.
Exit
100
UART Flow Timer Interrupt
Timer Interrupt
Advance bit count.
Y
Receive One Bit
Receive?
N
Transmit One Bit
101
UART Flow Transmit One Bit
Transmit One Bit
Y
Done?
Send STOP bit.
N
Rotate transmit byte and send next data bit.
Exit
102
UART Flow Receive One Bit
Receive One Bit
Y
N
Look for STOP (set error flag and abort if not
found).
Done?
First bit?
N
Y
Change timer setting to one full bit cell time.
Get next data bit and rotate into received byte.
Look for START (set error flag and abort if not
found).
Exit
103
80C51 Development Support
104
Signetics/Ceibo 80C51 Family Development Board

Supports 80C51 derivative microcontrollers that
have external program memory access and serial
port.
Connects to an MS-DOS compatible PC via serial
port (PC runs user interface software).
Line assembler and disassembler.
Register and memory contents may be viewed and
altered.
Source, memory, register windows.
32K user program memory on board.
Software breakpoints.

105
80C51 Family Development Board (continued)

Help screens.
Symbolic debugger.
Upload and download of object and hex files.
Fully documented. User's manual includes
experiments for learning the development board
and the 80C51 architecture.
Switches, LEDs, and a potentiometer are
included to allow simple experiments to be
performed without additional circuitry.

106
Supported Microcontrollers
Type 1 (full support via RS-232 to PC)
8031/51 8032/52 8xC31/51 8xC32/52 8xC451
8xC550 8xC552 8xC528 8xC652/654 8xC851
107
Supported Microcontrollers (continued)
Type 2 (limited support via I2C bus to type 1
device and PC)
8xC410 8xC751 8xC752

The 8xC751 and 8xC752 have no external program
memory capability and do not support user program
loading on the DB-51.
The 8xC410 does not have an on-chip UART and must
be communicated with via its I2C port. The
current version of the DB-51 does not support
user program loading on the 8xC410.

108
Demo Board Block Diagram
109
Uses for the Demo Board

Training vehicle for 80C51 product seminars.
Self training and experimentation system for
customers, FAEs, sales, factory, etc.
Basis for product demonstrations to customers.
Low cost development support, allows limited
hardware and software prototyping.

110
Emulators
Nohau Corp. 51 E. Campbell Ave. Campbell, CA
95008 (408) 866-1820 MetaLink Corp. 325 E.
Elliot Road, Suite 23 Chandler, AZ 85225 (602)
926-0797 Ceibo Ltd. 105 Gleason Rd. Lexington,
MA 02173 (617) 863-9927

BSO/Tasking
128 Technology Center
P.O.Box 9164
Waltham, MA 02254-9164
(617) 894-7800
Signum Systems
171 E. Thousand Oaks Blvd., 202
Thousand Oaks, CA 91360
(805) 371-4608
And others...

111
List of Programmer Manufacturer Contacts

Data I/O Corporation
10525 Willows Rd. N.E.
P.O. Box 97046
Redmond, WA 98073-9746
(206) 867-6899
Logical Devices, Inc.
1201 Northwest 65th Place
Ft. Lauderdale, FL 33309
(305) 974-0967
Signetics Co.
(contact nearest sales office)
And many others...

Ceibo Ltd. 105 Gleason Rd. Lexington, MA
02173 (617) 863-9927 North Valley Designs 1610B
Dell Avenue Campbell, CA 95008 (408)
866-4300 Needham's Electronics 4535 Orange Grove
Ave. Sacramento, CA 95841 (916) 924-8037
112
8051 Cross Assemblers

Metalink
macro cross assembler ASM51
Public Domain! Free on the Signetics BBS
2500 AD software
Macro assembler
Cross assembler
Simulator / debugger
And a host of others...

113
8051 C Compilers
2500 AD Software, Inc. 109 Brookdale Avenue P.O.
Box 480 Buena Vista, CO 81211 (800)
843-8144 Franklin Software, Inc. 888 Saratoga
Ave., 2 San Jose, CA 95129 (408) 296-8051 And
others...