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MICRO CONTROLLER 8051
UNIT IV
Mr. S. VINOD
LECTURER
EEE DEPARTMENT
Functional block diagram • Instruction format • addressing modes• Interrupt structure • Timer • I/O ports• Serial communication.
Microprocessor • CPU is stand-alone, RAM,
ROM, I/O, timer are separate• designer can decide on the
amount of ROM, RAM and I/O ports.
• expansive• versatility • general-purpose
Microcontroller•CPU, RAM, ROM, I/O and
timer are all on a single chip•fix amount of on-chip ROM,
RAM, I/O ports•for applications in which
cost, power and space are critical•single-purpose
Microprocessor vs Microcontroller
• Embedded system means the processor is embedded into that application.
• An embedded product uses a microprocessor or microcontroller to do one task only.
• In an embedded system, there is only one application software that is typically burned into ROM.
• Example-printer, keyboard, video game player
Embedded System
INTRODUCTION
• MCS-51 family, originally designed by Intel in the 1980’s
• Used in a large percentage of embedded systems
• Includes several on-chip peripherals, like timers and counters
• 128 bytes of on-chip data memory and up to 4K bytes of on-chip program memory
FEATURES • 8-bit CPU optimized for
control applications• Extensive Boolean
processing (single-bit logic) capabilities
• 64K Program Memory address space
• 64K Data Memory address space
• Up to 4K bytes of on-chip Program Memory
• 128 bytes of on-chip Data RAM
• 32 bi-directional and individually addressable I/O lines
• Two 16-bit timer/counters• 6-source/5-vector interrupt
structure with two priority levels
Block Diagram
CPU
On-chip RAM
On-chip ROM for program code
4 I/O Ports
Timer 0
Serial PortOSC
Interrupt Control
External interrupts
Timer 1
Timer/Counter
Bus Control
TxD RxDP0 P1 P2 P3
Address/Data
Counter Inputs
Pin Description of the 8051
(RXD)P3.0(TXD)P3.1
(T0)P3.4(T1)P3.5
(INT0)P3.2(INT1)P3.3
1234567891011121314151617181920
4039383736353433323130292827262524232221
P1.0P1.1P1.2P1.3P1.4P1.5P1.6P1.7RST
XTAL2XTAL1
GND
(RD)P3.7(WR)P3.6
VccP0.0(AD0)P0.1(AD1)P0.2(AD2)P0.3(AD3)P0.4(AD4)P0.5(AD5)P0.6(AD6)P0.7(AD7)EA/VPPALE/PROGPSENP2.7(A15)P2.6(A14)P2.5(A13)P2.4(A12)P2.3(A11)P2.2(A10)P2.1(A9)P2.0(A8)
8051
XTAL Connection to 8051
C2
30pF
C1
30pF
XTAL2
XTAL1
GND
•Using a quartz crystal oscillator•We can observe the frequency on the XTAL2 pin.
Architecture
• Memory Organization• Program Status Word• Interrupt Structure• Port Structures• Timer/Counters• Reset
Memory Organization
• Logical separation of program and data memory• Separate address spaces for Program (ROM) and
Data (RAM) Memory• Allow Data Memory to be accessed by 8-bit
addresses quickly and manipulated by 8-bit CPU
• Program Memory• Only be read, not written to• The address space is 16-bit, so maximum of 64K
bytes• Up to 4K bytes can be on-chip (internal) of 8051 core• PSEN (Program Store Enable) is used for access to
external Program Memory
Memory Organization
• Data Memory• Includes 128 bytes of on-chip Data Memory
which are more easily accessible directly by its instructions
• There is also a number of Special Function Registers (SFRs)
• Internal Data Memory contains four banks of eight registers and a special 32-byte long segment which is bit addressable by 8051 bit-instructions
• External memory of maximum 64K bytes is accessible by “movx”
Memory Organization• Internal Data Memory, 128 bytes
Program Status WordThe Program Status Word (PSW) contains several status bits that reflect the current state of the CPU.
• It contains the Carry bit, the Auxiliary Carry (for BCD operations), the two register bank select bits, the Overflow flag, a parity bit, and two user-definable status flags.
• The Carry bit, other than serving the functions of a Carry bit in arithmetic operations, also serves as the “Accumulator” for a number of Boolean operations.
• the Auxiliary Carry for BCD operations.• The bits RS0 and RS1 are used to select one of the four register
banks shown below. A number of instructions refer to these RAM locations as R0 through R7. The selection of which of the four banks is being referred to is made on the basis of the bits RS0 and RS1 at execution time.
• The parity bit reflects the number of 1’s in the Accumulator: P = 1 if the Accumulator contains an odd number of 1’s, and P = 0 if the Accumulator contains an even number of 1’s.
• Two bits in the PSW are uncommitted and may be used as general purpose status flags.
Interrupt Structure
• The 8051 provides 4 interrupt sources• Two external interrupts• Two timer interrupts
• Additional description follows in Operations chapter
Port Structures• The 8051 contains four I/O ports• All four ports are bidirectional• Each port has SFR (Special Function Registers P0 through P3) which works like a latch,
an output driver and an input buffer• Both output driver and input buffer of Port 0 and output driver of Port 2 are used for
accessing external memory• Accessing external memory works like this
• Port 0 outputs the low byte of external memory address (which is time-multiplexed with the byte being written or read)
• Port 2 outputs the high byte (only needed when the address is 16 bits wide)• Port 3 pins are multifunctional. The alternate functions are activated with the 1 written in
the corresponding bit in the port SFR
Read-Modify-Write Feature
• When reading a port some instructions read the latch and others read the pin
• The instructions that read the latch rather than the pin are the ones that read a value (possibly change it), an then rewrite it to the latch are called “read-modify-write” instructions
Timer/Counters• The 8051 has two 16-bit Timer/Counter registers
• Timer 0 • Timer 1
• Both can work either as timers or event counters• Both have four different operating modes from which to select.
• Mode 0 (13-bit Timer)• Mode 1 (16-bit Timer)• Mode 2 (8-bit Timer with Auto-Reload)• Mode 3 (Two 8-bit Timers)
Instruction Set
• Optimized for 8-bit control applications• Fast addressing modes for accessing
internal RAM in order to facilitate byte operations on small data structures
• Good for systems that require a lot of Boolean processing because of its extensive support for one-bit variables as a separate data type
Addressing Modes (1/3)
• Direct Addressing• Operand is specified by an 8-bit address field in the
instruction• This address mode is possible only for addressing
internal Data RAM and SFRs• Indirect Addressing
• The instruction specifies a register which contains the address of the operand
• The address register for 8-bit addresses can be R0 or R1 of the selected bank, or the Stack Pointer
• The address register for 16-bit addresses can only be 16-bit “data pointer” register, DPTR
• Both internal and external RAM can be indirectly addressed
Addressing Modes (2/3)
• Register Instructions• Special instructions are used for accessing four
register banks (containing R0 to R7)• This instructions have 3-bit register specification
within the opcode• This way of accessing registers is much more efficient
because of no need for the address byte• When such instruction is executed one of registers in
selected ban is accessed• Register bank is selected by two bank select bits in
PSW
Addressing Modes (3/3)
• Register-Specific Instructions• These are instructions which are specific to a certain
register and they don’t need an address byte (they always operate with the same register)
• Immediate Constants• The value of a constant follows the opcode• MOV A, #10 – loads the Accumulator with the decimal
number 10• Indexed Addressing
• Only Program Memory can be accessed and it can be a read
• Used for reading look-up tables in Program Memory and “case jump” instruction
Instruction Types of 8051
• Arithmetic Instructions• Logical Instructions• Data Transfers• Lookup Tables• Boolean Instructions• Jump Instructions
8051 Registers
The Instruction Set and Addressing Modes
• Rn Register R7-R0 of the currently selected Register Bank.
• direct 8-bit internal data location’s address. This could be an Internal Data RAM location (0-127) or a SFR [i.e., I/O port, control register, status register,etc.(128 255)].
• @Ri 8-bit internal data RAM location (0-255) addressed indirectly through register R1or R0.
• #data 8-bit constant included in instruction.
• #data 16 16-bit constant included in instruction.
• addr 16 16-bit destination address. Used by LCALL and LJMP. A branch can be anywhere within the 64K byte Program Memory address space.
• addr 11 11-bit destination address. Used by ACALL and AJMP. The branch will be within the same 2K byte page of program memory as the first byte of the following instruction.
• rel Signed (two’s complement) 8-bit offset byte. Used by SJMP and all conditional jumps. Range is -128 to +127 bytes relative to first byte of the following instruction.
• bit Direct Addressed bit in Internal Data RAM or Special Function Register.
ADD A,Rn Add register to Accumulator ADD A,direct Add direct byte to Accumulator ADD A,@Ri Add indirect RAM to Accumulator ADD A,#data Add immediate data to Accumulator ADDC A,Rn Add register to Accumulator with CarryADDC A,direct Add direct byte to Accumulator with CarryADDC A,@Ri Add indirect RAM to Accumulator with CarryADDC A,#data Add immediate data to Acc with Carry SUBB A,Rn Subtract Register from Acc with borrowSUBB A,direct Subtract direct byte from Acc with borrowSUBB A,@Ri Subtract indirect RAM from ACC with borrowSUBB A,#data Subtract immediate data from Acc with borrowINC A Increment Accumulator INC Rn Increment register INC direct Increment direct byte INC @Ri Increment direct RAM DEC A Decrement Accumulator DEC Rn Decrement Register DEC direct Decrement direct byte DEC @Ri Decrement indirect RAM INC DPTR Increment Data Pointer MUL AB Multiply A & B DIV AB Divide A by B DA A Decimal Adjust Accumulator
ARITHMETIC OPERATIONS
LOGICAL OPERATIONANL A,Rn AND Register to Accumulator ANL A,direct AND direct byte to Accumulator ANL A,@Ri AND indirect RAM to Accumulator ANL A,#data AND immediate data to Accumulator ANL direct,A AND Accumulator to direct byte ANL direct,#data AND immediate data to direct byte ORL A,Rn OR register to Accumulator ORL A,direct OR direct byte to Accumulator ORL A,@Ri OR indirect RAM to Accumulator ORL A,#data OR immediate data to Accumulator ORL direct,A OR Accumulator to direct byte ORL direct,#data OR immediate data to direct byte XRL A,Rn Exclusive-OR register to Accumulator XRL A,direct Exclusive-OR direct byte to AccumulatorXRL A,@Ri Exclusive-OR indirect RAM to AccumulatorXRL A,#data Exclusive-OR immediate data to
AccumulatorXRL direct,A Exclusive-OR Accumulator to direct byteXRL direct,#data Exclusive-OR immediate data to direct byte
LOGICAL OPERATION
CLR A Clear Accumulator
CPL A Complement Accumulator
RL A Rotate Accumulator Left
RLC A Rotate Accumulator Left through the Carry
RR A Rotate Accumulator Right
RRC A Rotate Accumulator Right through the Carry
SWAP A Swap nibbles within the Accumulator
Data TransfersMOV A,Rn Move register to Accumulator
MOV A,direct Move direct byte to Accumulator
MOV A,@Ri Move indirect RAM to Accumulator
MOV A,#data Move immediate data to Accumulator
MOV Rn,A Move Accumulator to register
MOV Rn,direct Move direct byte to register
MOV Rn,#data Move immediate data to register
MOV direct,A Move Accumulator to direct byte
MOV direct,Rn Move register to direct byte
MOV direct,direct Move direct byte to direct
MOV direct,@Ri Move indirect RAM to direct byte
MOV direct,#data Move immediate data to direct byte
MOV @Ri,A Move Accumulator to indirect RAM
MOV @Ri,direct Move direct byte to indirect RAM
Data TransfersMOV @Ri,#data Move immediate data to indirect RAM
MOV DPTR,#data16 Load Data Pointer with a 16-bit constant
MOVC A,@A+DPTR Move Code byte relative to DPTR to Acc
MOVC A,@A+PC Move Code byte relative to PC to Acc
MOVX A,@Ri Move External RAM (8-bit addr) toAcc
MOVX A,@DPTR Move External RAM (16-bit addr) to Acc
MOVX @Ri,A Move Acc to External RAM (8-bit addr)
MOVX @DPTR,A Move Acc to External RAM (16-bitaddr)
PUSH direct Push direct byte onto stack
POP direct Pop direct byte from stack
XCH A,Rn Exchange register with Accumulator
XCH A,direct Exchange direct byte with Accumulator
XCH A,@Ri Exchange indirect RAM with Accumulator
XCHD A,@Ri Exchange low-order Digit indirect RAM with Acc
BOOLEAN VARIABLE MANIPULATION
CLR C Clear Carry CLR bit Clear direct bit SETB C Set Carry SETB bit Set direct bit CPL C Complement Carry CPL bit Complement direct bit ANL C,bit AND direct bit to CARRY ANL C,/bit AND complement of direct bit to Carry ORL C,bit OR direct bit to Carry ORL C,/bit OR complement of direct bit to Carry MOV C,bit Move direct bit to Carry MOV bit,C Move Carry to direct bit JC rel Jump if Carry is set JNC rel Jump if Carry not setJB bit,rel Jump if direct Bit is set JNB bit,rel Jump if direct Bit is Not set JBC bit,rel Jump if direct Bit is set & clear bit
PROGRAM BRANCHING
ACALL addr11 Absolute Subroutine Call LCALL addr16 Long Subroutine Call RET Return from Subroutine RETI Return from interrupt AJMP addr11 Absolute Jump LJMP addr16 Long Jump SJMP rel Short Jump (relative addr) JMP @A+DPTR Jump indirect relative to the DPTR JZ rel Jump if Accumulator is Zero JNZ rel Jump if Accumulator is Not Zero CJNE A,direct,rel Compare direct byte to Acc and Jump if Not EqualCJNE A,#data,rel Compare immediate to Acc and Jump if Not EqualCJNE Rn,#data,rel Compare immediate to register and Jump if Not
EqualCJNE @Ri,#data,rel Compare immediate to indirect and Jump if Not
EqualDJNZ Rn,rel Decrement register and Jump if NotZeroDJNZ direct,rel Decrement direct byte and Jump ifNot ZeroNOP No Operation
Lookup Tables
Timer/Counters• 8051 has two 16-bit Timer/Counter registers
• Timer/Counter 0• Timer/Counter 1
• These registers can be used as timers or as event counters• When operating as a timer, the timer/counter runs for a programme
length of time, then issues an interrupt request.• When operating as a counter, the timer/counter counts negative
transitions on an external pin. After a preset number of counts, the counter issues an interrupt request.
• Both registers have additional four operating modes
Timer/Counter Modes
• The selection for “Timer” or “Counter” is done by control bits C/T in the TMOD register
• Both Timer/Counters have four operating modes, which Modes 0, 1 and 2 are the same for both Timer/Counters, Mode 3 is different
• Modes are selected by bit pairs (M1, M0) in TMOD SFR
• Another SFR used for work with Timer/Counters is TCON containing flag (TFx) and control (TRx) bits
TMOD REGISTER
T CON REGISTER
Timer 0
• Timer 0 functions as either a timer or event counter in four modes of operation. Timer 0 is controlled by the four lower bits of the TMOD register (see Table 2-5) and bits 0, 1, 4 and 5 of the TCON register (see Table 2-3). TMOD register selects the method of timer gating (GATE0), timer or counter operation (T/C0#) and mode of operation (M10 and M00). The TCON register provides timer 0 control functions: overflow flag (TF0), run control bit (TR0), interrupt flag (IE0) and interrupt type control bit (IT0).
• For normal timer operation (GATE0= 0), setting TR0 allows TL0 to be incremented by the selected input. Setting GATE0 and TR0 allows external pin INT0# to control timer operation.
• Timer 0 overflow (count rolls over from all 1s to all 0s) sets TF0 flag, generating an interrupt request.
• It is important to stop timer/counter before changing mode.
Mode 0 (13-bit Timer)• Mode 0 configures timer 0 as a 13-bit timer which is set up as an 8-bit timer (TH0 register) and
the lower five bits of the TL0 register. The upper three bits of TL0 register are indeterminate and should be ignored.
• Pre scalar overflow increments the TH0 register. As the count rolls over from all 1’s to all 0’s, it sets the timer interrupt flag TF0. The counted input is enabled to the Timer when TR0 = 1 and either GATE = 0 or INT0 = 1.
• (Setting GATE = 1 allows the Timer to be controlled by external input INT0, to facilitate pulse width measurements). TR0 is a control bit in the Special Function register TCON, GATE is in TMOD.
• Mode 0 operation is the same for Timer 0 as for Timer 1. Substitute TR0, TF0 and INT0 for the corresponding Timer 1 signals. There are two different GATE bits, one for Timer 1 (TMOD.7) and one for Timer 0 (TMOD.3).
Mode 1 (16-bit Timer)• Mode 1 is the same as Mode 0, except that the Timer register is being
run with all 16• bits. Mode 1 configures timer 0 as a 16-bit timer with the TH0 and TL0
registers connected in cascade. The selected input increments the TL0 register.
Mode 2 (8-bit Timer with Auto-Reload)
• Mode 2 configures timer 0 as an 8-bit timer (TL0 register) that automatically reloads from the TH0 register. TL0 overflow sets TF0 flag in the TCON register and reloads TL0 with the contents of TH0, which is preset by software.
• When the interrupt request is serviced, hardware clears TF0. The reload leaves TH0 unchanged. The next reload value may be changed at any time by writing it to the TH0 register.
• Mode 2 operation is the same for Timer/Counter 1.
Mode 3 (Two 8-bit Timers)• Mode 3 configures timer 0 so that registers TL0 and TH0 operate as separate 8-bit timers.• This mode is provided for applications requiring an additional 8-bit timer or counter. TL0
uses the timer 0 control bits C/T0# and GATE0 in the TMOD register, and TR0 and TF0 in the TCON register in the normal manner.
• TH0 is locked into a timer function (counting FPER /6) and takes over use of the timer 1 interrupt (TF1) and run control (TR1) bits. Thus, operation of timer 1 is restricted when timer 0 is in mode 3.
Interrupt
• 8051 provides 4 interrupt sources• 2 external interrupts• 2 timer interrupts
• They are controlled via two SFRs, IE and IP
• Each interrupt source can be individually enabled or disabled by setting or clearing a bit in IE (Interrupt Enable). IE also exists a global disable bit, which can be cleared to disable all interrupts at once
Interrupt
• Each interrupt source can also be individually set to one of two priority levels by setting or clearing a bit in IP (Interrupt Priority)
• A low-priority interrupt can be interrupted by high-priority interrupt, but not by another low-priority one
• A high-priority interrupt can’t be interrupted by any other interrupt source
• If interrupt requests of the same priority level are received simultaneously, an internal polling sequence determines which request is serviced, so within each priority lever there is a second priority structure
Interrupt
• This internal priority structure is determined by the polling sequence, shown in the following table
External Interrupts
• External interrupts ~INT0 and ~INT1 have two ways of activation• Level-activated• Transition-activated
• This depends on bits IT0 and IT1 in TCON• The flags that actually generate these interrupts are bits
IE0 and IE1 in TCON• On-chip hardware clears that flag that generated an
external interrupt when the service routine is vectored to, but only if the interrupt was transition-activated
• When the interrupt is level-activated, then the external requesting source is controlling the request flag, not the on-chip hardware
Timer 0 and Timer 1 Interrupts• Timer interrupts are generated by TF0 and
TF1 flags in their respective Timer/Counter registers
• Similarly like in the case of transition-activated external interrupts, the flag that generated an interrupt is cleared by the on-chip hardware when the service routine is vectored to
Handling of Interrupts• When interrupt occurs (or correctly, when the flag for an enabled interrupt is
found to be set 1), the interrupt system generates an LCALL to the appropriate location in Program Memory, unless some other conditions block the interrupt
• Several conditions can block an interrupt• An interrupt of equal or higher priority level is already in progress• The current (polling) cycle is not the final cycle in the execution of the
instruction in progress• The instruction in progress is RETI or any write to IE or IP registers
• If an interrupt flag is active but not being responded to for one of the above conditions, must be still active when the blocking condition is removed, or the denied interrupt will not be serviced
• Next step is saving the registers on stack. The hardware-generated LCALL causes only the contents of the Program Counter to be pushed onto the stack, and reloads the PC with the beginning address of the service routine
• In some cases it also clears the flag that generated the interrupt, and in other cases it doesn’t. It clears an external interrupt flag (IE0 or IE1) only if it was transition-activated.
Handling of Interrupts
• Having only PC be automatically saved gives programmer more freedom to decide how much time to spend saving other registers. Programmer must also be more careful with proper selection, which register to save
• The service routine for each interrupt begins at a fixed location. The interrupt locations are spaced at 8-byte interval, beginning at 0003H for External Interrupt 0, 000BH for Timer 0, 0013H for External Interrupt 1 and 001BH for Timer 1, shown in the following tables
• Execution of service routine continues from that
location until the end, that is until it encounters RETI.
RETI instruction does two things• It informs the processor that this interrupt
Routine is finished• Secondly, reloads the PC from the top bytes
from the stack
Reset
• The reset input is RST pin• To accomplish a reset the RST pin must be held high for
at least two machine cycles• In the response on the RST signal, CPU generates an
internal reset• The external reset signal is asynchronous to the internal
clock• In the internal reset algorithm, 0s are written to all the
SFRs except the port latches and Stack Pointer• The port latches are initialized to FFH and Stack Pointer
to 07H• Driving ALE and PSEN pins to 0 while reset is active
could cause the device to go into an indeterminate state• The internal RAM is not affected by reset. On power up
the RAM content is indeterminate
IE: Interrupt Enable Register(bit addressable)
• If the bit is 0, the corresponding interrupt is disabled. Otherwise, the interrupt is enabled.
IP: Interrupt Priority Register(bit addressable)
• If the bit is 0, the corresponding interrupt has a lower priority and if the bit is 1, the interrupt has a higher priority
8051 CONNECTION TO RS232
• RxD and TxD pins in the 8051• 8051 has two pins used for transferring and
receiving data serially• TxD and RxD are part of the port 3 group • pin 11 (P3.1) is assigned to TxD• pin 10 (P3.0) is designated as RxD• these pins are TTL compatible• require a line driver to make them RS232
compatible• driver is the MAX232 chip
8051 CONNECTION TO RS232MAX232• converts from RS232 voltage levels to TTL voltage levels• uses a +5 V power source• MAX232 has two sets of line drivers for transferring and
receiving data• line drivers used for TxD are called T1 and T2• line drivers for RxD are designated as R1 and R2• T1 and R1 are used together for TxD and RxD of the 8051• second set is left unused.
MAX233• MAX233 performs the same job as the MAX232• eliminates the need for capacitors• much more expensive than the MAX232
8051 CONNECTION TO RS232
Figure (a) Inside MAX232(b) its Connection to the 8051 (Null Modem)
8051 CONNECTION TO RS233
Figure (a) Inside MAX233(b) Its Connection to the 8051 (Null Modem)
8051 SERIAL PORT PROGRAMMING IN ASSEMBLY
• Baud rate in the 8051• serial communications of the 8051 with the COM port of the
PC• must make sure that the baud rate of the 8051 system
matches the baud rate of the PC's COM port• Baud rate in the 8051
• baud rate in the 8051 is programmable• done with the help of Timer 1• relationship between the crystal frequency and the baud rate in
the 8051• 8051 divides the crystal frequency by 12 to get the machine cycle
frequency• XTAL = 11.0592 MHz, the machine cycle frequency is 921.6 kHz• 8051's UART divides the machine cycle frequency of 921.6 kHz
by 32 once more before it is used by Timer 1 to set the baud rate• 921.6 kHz divided by 32 gives 28,800 Hz• Timer 1 must be programmed in mode 2, that is 8-bit, auto-reload
8051 SERIAL PORT PROGRAMMING IN ASSEMBLY
Timer 1 TH1 Register Values for Various Baud Rates
With XTAL = 11.0592 MHz, find the TH1 value needed to have the following baud rates. (a)
9600 (b) 2400 (c) 1200
• machine cycle frequency= 11.0592 MHz / 12 = 921.6 kHz
• Timer 1 frequency provided by 8051 UART= 921.6 kHz / 32 = 28,800 Hz
(a) 28,800 / 3 = 9600 where -3 = FD (hex)(b) 28,800 / 12 = 2400 where -12 = F4 (hex)
(c) 28,800 / 24 = 1200 where -24 = E8 (hex)
8051 SERIAL PORT PROGRAMMING IN ASSEMBLY
11.0592 MHzXTAL oscillator
8051 SERIAL PORT PROGRAMMING IN ASSEMBLY
• SBUF (serial buffer) register
• A byte of data to be transferred via the TxD line must be placed in the SBUF registerSBUF holds the byte of data when it is received by the RxD line
• can be accessed like any other register
MOV SBUF,#'D' ;load SBUF=44H, ASCII for 'D‘MOV SBUF,A ;copy accumulator into SBUFMOV A,SBUF ;copy SBUF into accumulator
• when a byte is written, it is framed with the start and stop bits and transferred serially via the TxD pin
• when the bits are received serially via RxD, it is deframe by eliminating the stop and start bits, making a byte out of the data received, and then placing it in the SBUF
8051 SERIAL PORT PROGRAMMING IN ASSEMBLY
• SCON (serial control) register• to program the start bit, stop bit, and data
bits
SCON Serial Port Control Register (Bit-Addressable)
SERIAL PORT PROGRAMMING IN ASSEMBLY
• SM0 and SM1 determine the mode• only mode 1 is important• For mode 1 SM0= 0, SM1=1• when mode 1 is chosen, the data framing is 8 bits, 1 stop
bit, and 1 start bit• compatible with the COM port of PCs• mode 1 allows the baud rate to be variable and is set by
Timer 1 of the 8051• for each character a total of 10 bits are transferred,
where the first bit is the start bit, followed by 8 bits of data, and finally 1 stop bit.
SERIAL PORT PROGRAMMING IN ASSEMBLY• REN (receive enable) • REN=1, allows 8051 to receive data on the RxD• if 8051 is to both transfer and receive data, REN must be set to
1• REN=0, the receiver is disabled• TI (transmit interrupt)
• when 8051 finishes the transfer of the 8-bit character, it raises the TI flag to indicate that it is ready to transfer another byte
• RI (receive interrupt)• when the 8051 receives data serially via RxD, it places the
byte in the SBUF register• then raises the RI flag bit to indicate that a byte has been
received and should be picked up before it is lost
• Program to transfer data serially• TMOD register is loaded with the value 20H• TH1 is loaded with value to set the baud rate• SCON register is loaded with the value 50H• TR1 is set to 1 to start Timer1• TI is cleared by the "CLR TI" instruction• transmit character byte is written into the SBUF register• TI flag bit is monitored to see if the character has been transferred
completely• to transfer the next character, go to Step 5.program to transfer letter "A" serially at 4800 baud
Write a program to transfer the message "YES" serially at 9600 baud, 8-bit data, 1 stop bit. Do
this continuously.
PROGRAMMING IN ASSEMBLY
• Importance of the TI flag• check the TI flag bit, we know whether can transfer another byte• TI flag bit is raised by the 8051• TI flag cleared by the programmer• writing a byte into SBUF before the TI flag bit is raised, may lead to loss
of a portion of the byte being transferred • Program to receive data serially
• TMOD register is loaded with the value 20H• TH1 is loaded with value set the baud rate• SCON register is loaded with the value 50H• TR1 is set to 1 to start Timer 1• RI is cleared with the "CLR RI" instruction• RI flag bit is monitored to see if an entire character has been
received yet• RI=1 SBUF has the byte, its contents are moved into a safe
place• to receive the next character, go to Step 5
Program the 8051 to receive bytes of data serially, and put them in P1. Set the baud rate
at 4800, 8-bit data, and 1 stop bit.
• Importance of the RI flag bit• it receives the start bit, next bit is the first bit of the character• when the last bit is received, a byte is formed and placed in
SBUF• when stop bit is received, makes RI = 1• when RI=1, received byte is in the SBUF register, copy SBUF
contents to a safe place• after the SBUF contents are copied the RI flag bit must be
cleared to 0
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