- Interrupt In 8051 Microcontroller
- Proton Basic Serial Interrupt In 8051 Software
- Proton Basic Serial Interrupt In 8051 Code
- Interrupt In 8051
- Proton Basic Serial Interrupt In 8051 System
- Proton Basic Serial Interrupt In 8051 Numbers
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An interrupt is a signal to the processor of the occurrence of an event by hardware or software. The processor may choose to accept or ignore this signal. The response of the processor to an interrupt is configured with the help of registers such as INTCON, PIR, PIE and IPR registers as specified in our previous chapter on Interrupt Handling in. Where are the interrupt vectors located in the microprocessor’s memory? How many different interrupt vectors are found in the interrupt vector table? Which interrupt vectors are reserved by Intel? Explain how a type 0 interrupt occurs. Where is the interrupt descriptor table located for protected mode operation?
In the previous 8051 Microcontroller Tutorial, we have seen the Instruction Set and Addressing Modes. In this tutorial, we will take a look at the 8051 Microcontroller Special Function Registers or SFRs.
If you remember from the 8051 Microcontroller Memory Organization Tutorial, the internal RAM or Data Memory of the 8051 Microcontroller is divided in to General Purpose Registers, Bit Addressable Registers, Register Banks and Special Function Registers or SFRs.
The 8051 Microcontroller Special Function Registers are used to program and control different hardware peripherals like Timers, Serial Port, I/O Ports etc. In fact, by manipulating the 8051 Microcontroller Special Function Registers (SFRs), you can assess or change the operating mode of the 8051 Microcontroller.
As a reminder, the following image shows you the basic structure of 8051 Microcontroller’s Internal RAM.
8051 Microcontroller Special Function Registers (SFRs)
The 8051 Microcontroller Special Function Registers act as a control table that monitor and control the operation of the 8051 Microcontroller. If you observe in Internal RAM Structure, the Address Space from 80H to FFH is allocated to SFRs.
Out of these 128 Memory Locations (80H to FFH), there are only 21 locations that are actually assigned to SFRs. Each SFR has one Byte Address and also a unique name which specifies its purpose.
Since the SFRs are a part of the Internal RAM Structure, you can access SFRs as if you access the Internal RAM. The main difference is the address space: first 128 Bytes (00H to 7FH) is for regular Internal RAM and next 128 Bytes (80H to FFH) is for SFRs.
TIP: As only 21 of the possible 128 SFR memory locations are assigned, it is recommended that the remaining registers or memory locations are not accessed during programming.
Before going further, get an idea on 8051 MICROCONTROLLER ARCHITECTURE.
List of 8051 Microcontroller Special Function Registers
- A or ACC
- B
- DPL
- DPH
- IE
- IP
- P0
- P1
- P2
- P3
- PCON
- PSW
- SCON
- SBUF
- SP
- TMOD
- TCON
- TL0
- TH0
- TL1
- TH1
Categories of 8051 Microcontroller Special Function Registers
All the 21 8051 Microcontroller Special Function Registers (SFRs) along with their functions and Internal RAM Address is given in the following table.
There are many ways to categorize these 21 Special Function Registers but I find the following way as an appropriate one. The 21 Special Function Registers of 8051 Microcontroller are categorized in to seven groups. They are:
Math or CPU Registers: A and B
Status Register: PSW (Program Status Word)
Pointer Registers: DPTR (Data Pointer – DPL, DPH) and SP (Stack Pointer)
I/O Port Latches: P0 (Port 0), P1 (Port 1), P2 (Port 2) and P3 (Port 3)
Peripheral Control Registers: PCON, SCON, TCON, TMOD, IE and IP
Peripheral Data Registers: TL0, TH0, TL1, TH1 and SBUF
CPU or Math Registers
A or Accumulator (ACC)
The Accumulator or Register A is the most important and most used 8051 Microcontroller SFRs. The Register A is located at the address E0H in the SFR memory space. The Accumulator is used to hold the data for almost all the ALU Operations.
Some of the operations where the Accumulator is used are:
Interrupt In 8051 Microcontroller
- Arithmetic Operations like Addition, Subtraction, Multiplication etc.
- Logical Operations like AND, OR, NOT etc.
- Data Transfer Operations (between 8051 and External Memory)
The name “Accumulator” came from the fact this register is used to accumulate (or store) the result of all Arithmetic and most of the Logical Operations.
B (Register B)
The B Register is used along with the ACC in Multiplication and Division operations. These two operations are performed on data that are stored only in Registers A and B. During Multiplication Operation, one of the operand (multiplier or multiplicand) is stores in B Register and also the higher byte of the result.
In case of Division Operation, the B Register holds the divisor and also the remainder of the result. It can also be used as a General Purpose Register for normal operations and is often used as an Auxiliary Register by Programmers to store temporary results.
Register B is located at the address F0H of the SFR Address Space.
Program Status Word (PSW)
The PSW or Program Status Word Register is also called as Flag Register and is one of the important SFRs. The PSW Register consists of Flag Bits, which help the programmer in checking the condition of the result and also make decisions.
Flags are 1-bit storage elements that store and indicate the nature of the result that is generated by execution of certain instructions. The following image shows the contents of the PSW Register.
The following table describes the function of each flag.
Pointer Registers
Data Pointer (DPTR – DPL and DPH)
The Data Pointer is a 16-bit Register and is physically the combination of DPL (Data Pointer Low) and DPH (Data Pointer High) SFRs. The Data Pointer can be used as a single 16-bit register (as DPTR) or two 8-bit registers (as DPL and DPH).
DPTR doesn’t have a physical Memory Address but the DPL (Lower Byte of DPTR) and DPH (Higher Byte of DPTR) have separate addresses in the SFR Memory Space. DPL = 82H and DPH = 83H.
The DPTR Register is used by the programmer addressing external memory (Program – ROM or Data – RAM).
Stack Pointer (SP)
SP or Stack Pointer points out to the top of the Stack and it indicates the next data to be accessed. Stack Pointer can be accesses using PUSH, POP, CALL and RET Instructions. The Stack Pointer is an 8-bit register and upon reset, the Stack Pointer is initialized with 07H.
When writing a new data byte into the stack, the SP (Stack Pointer) is automatically incremented by 1 and the new data is written at an address SP+1. When reading data from stack, the data is retrieved from the Address in SP and after that the SP is decremented by 1 (SP-1).
I/O Port Registers (P0, P1, P2 and P3)
The 8051 Microcontroller four Ports which can be used as Input and/or Output. These four ports are P0, P1, P2 and P3. Each Port has a corresponding register with same names (the Port Registers are also P0, P1, P2 and P3). The addresses of the Port Registers are as follows: P0 – 80H, P1 – 90H, P2 – A0H and P2 – B0H.
Each bit in these SFRs corresponds to one physical Pin in the 8051 Microcontroller. All these Port Registers are both Bit Addressable and Byte Addressable. Writing 1 or 0 on a Port Register Bit will reflect as an appropriate voltage (5V and 0V) on the corresponding Pin.
If a Port Bit is SET (declared as 1), the corresponding Port Pin will be configured as Input and similarly if a Port Bit is CLEARED (declared as 0), the corresponding Port Pin is configured as Output. Upon reset, all the Port Bits are SET (1) and hence, all the Port Pins are configured as Inputs.
Peripheral Control Registers
PCON (Power Control)
The PCON or Power Control register, as the name suggests is used to control the 8051 Microcontroller’s Power Modes and is located at 87H of the SFR Memory Space. Using two bits in the PCON Register, the microcontroller can be set to Idle Mode and Power Down Mode.
During Idle Mode, the Microcontroller will stop the Clock Signal to the ALU (CPU) but it is given to other peripherals like Timer, Serial, Interrupts, etc. In order to terminate the Idle Mode, you have to use an Interrupt or Hardware Reset.
In the Power Down Mode, the oscillator will be stopped and the power will be reduced to 2V. To terminate the Power Down Mode, you have to use the Hardware Reset.
Apart from these two, the PCON Register can also be used for few additional purposes. The SMOD Bit in the PCON Register is used to control the Baud Rate of the Serial Port.
There are two general purpose Flag Bits in the PCON Register, which can be used by the programmer during execution.
SCON (Serial Control)
The Serial Control or SCON SFR is used to control the 8051 Microcontroller’s Serial Port. It is located as an address of 98H. Using SCON, you can control the Operation Modes of the Serial Port, Baud Rate of the Serial Port and Send or Receive Data using Serial Port.
SCON Register also consists of bits that are automatically SET when a byte of data is transmitted or received.
Serial Port Mode Control Bits
SM0 | SM1 | Mode | Description | Baud Rate |
0 | 0 | 0 | 8-Bit Synchronous Shift Register Mode | Fixed Baud Rate ( Frequency of oscillator / 12) |
0 | 1 | 1 | 8-bit Standard UART mode | Variable Baud Rate (Can be set by Timer 1) |
1 | 0 | 2 | 9-bit Multiprocessor Comm. mode | Fixed Baud Rate ( Frequency of oscillator / 32 or Frequency of oscillator / 64 |
1 | 1 | 3 | 9-bit Multiprocessor Comm. mode | Variable Baud Rate (Can be set by Timer 1) |
TCON (Timer Control)
Timer Control or TCON Register is used to start or stop the Timers of 8051 Microcontroller. It also contains bits to indicate if the Timers has overflowed. The TCON SFR also consists of Interrupt related bits.
TMOD (Timer Mode)
The TMOD or Timer Mode register or SFR is used to set the Operating Modes of the Timers T0 and T1. The lower four bits are used to configure Timer0 and the higher four bits are used to configure Timer1.
The Gatex bit is used to operate the Timerx with respect to the INTx pin or regardless of the INTx pin.
GATE1 = 1 > Timer1 is operated only if INT1 is SET.
GATE1 = 0 > Timer1 is operates irrespective of INT1 pin.
GATE0 = 1 > Timer0 is operated only if INT0 is SET.
GATE0 = 0 > Timer0 is operates irrespective of INT0 pin.
The C/Tx bit is used selects the source of pulses for the Timer to count.
C/T1 = 1 > Timer1 counts pulses from Pin T1 (P3.5) (Counter Mode)
C/T1 = 0 > Timer1 counts pulses from internal oscillator (Timer Mode)
C/T0 = 1 > Timer0 counts pulses from Pin T0 (P3.4) (Counter Mode)
C/T0 = 0 > Timer0 counts pulses from internal oscillator (Timer Mode)
TxM0 | TxM1 | Mode | Description |
0 | 0 | 0 | 13-bit Timer Mode (THx – 8-bit and TLx – 5-bit) |
0 | 1 | 1 | 16-bit Timer Mode |
1 | 0 | 2 | 8-bit Auto Reload Timer Mode |
1 | 1 | 3 | Two 8-bit Timer Mode or Split Timer Mode |
NOTE: x = 0 for Timer 0 and x = 1 for Timer 1.
IE (Interrupt Enable)
The IE or Interrupt Enable Register is used to enable or disable individual interrupts. If a bit is SET, the corresponding interrupt is enabled and if the bit is cleared, the interrupt is disabled. The Bit7 of the IE register i.e. EA bit is used to enable or disable all the interrupts.
IP (Interrupt Priority)
Proton Basic Serial Interrupt In 8051 Software
The IP or Interrupt Priority Register is used to set the priority of the interrupt as High or Low. If a bit is CLEARED, the corresponding interrupt is assigned low priority and if the bit is SET, the interrupt is assigned high priority.
Peripheral Data Registers
Proton Basic Serial Interrupt In 8051 Code
SBUF (Serial Data Buffer)
Interrupt In 8051
The Serial Buffer or SBUF register is used to hold the serial data while transmission or reception.
Proton Basic Serial Interrupt In 8051 System
TL0/TH0 (Timer 0 Low/High)
The Timer 0 consists of two SFRs: TL0 and TH0. The TL0 is the lower byte and the TH0 is the higher byte and together they form a 16-bit Timer0 Register.
TL1/TH1 (Timer 1 Low/High)
The TL1 and TH1 are the lower and higher bytes of the Timer 0.
Proton Basic Serial Interrupt In 8051 Numbers
In this tutorial, we have seen the 8051 Microcontroller Special Function Registers (SFRs), their addresses, structures, reset values etc.