embedded systems
TRANSCRIPT
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EMBEDDED SYSTEMS
Prepared by
G.Manjunathan ME.,
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What is general purpose system?• A computer system that can do many
functionalities depending on • Available hardware
• Installed programs
Examples
• PCs
• Laptops
• Servers
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What is an Embedded systems ?
• An embedded system is a special-purposecomputer system designed to perform adedicated function
• A combination of hardware and softwarewhich together form a component of a largermachine.
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Block Diagram of an Embedded System
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Essential Components
• Microprocessor / Microcontroller
• Sensors
• Converters (A-D and D-A)
• Actuators
• Memory (On-chip and Off chip)
• Communication path with the interacting environment
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Important Units Of Microprocessor/Controller
• CPU: Central Processing Unit• I/O: Input /Output• Bus: Address bus & Data bus• Memory: RAM & ROM• Timer• Interrupt
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CPUGeneral-Purpose Micro-
processorRAM ROM I/O Port Timer
Serial COM Port
Data Bus
Address Bus
General-Purpose Microprocessor System
• CPU for Computers• No RAM, ROM, I/O on CPU chip itself• Example--Intel’s x86: 8086,8088,80386,80486,
PentiumMany chips on mother board
General-purpose Microprocessor
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RAM ROM
I/O PortTimerSerial COM Port
Microcontroller
CPU
• A smaller computer.• On-chip RAM, ROM, I/O ports...• Example:- Motorola’s 6811, Intel’s 8051 and
PIC 16X
A single chip
Microcontroller
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Microprocessor Vs Microcontroller
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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.
• expensive• general-purpose• Ex. 8085,8086 mp, Motorola 6800,
Intel’s 8086, etc.
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• Ex. 8051, PIC mc, Motorola
MC’s, Phillips, etc.
Microprocessor v/s Microcontroller
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ARCHITECTURE
Instruction Set Based
CISC & RISC
Memory Access Based
HARVARD &
VON-NUEMANN
Architecture
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CISC Vs RISC
CISC
• hardware complexity is
high
• multi clock complex
instructions
• Small codes sizes
• Transistors used for
storing complex
instructions
• pipelining is not possible
due to uneven process
time
RISC
• hardware complexity is low
• Single clock Reduced
instructions only
•Low cycles/sec
• Spends more transistors on
memory registers
• instructions execute in a
uniform amount of time (i.e. one
clock), pipelining is possible.2444
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Application areas
Automotive electronics
Aircraft electronics
Trains
Telecommunication
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Automobiles
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Consumer electronics
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Industry Automation
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Telecommunication
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Medical systems
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Embedded Medical Equipment
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Application areas
22
• Authentication
• Military applications
• Medical systems
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Application areas
Consumer electronics
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• Smart buildings
• Fabrication equipment
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Traffic LightDVD player
Digital clockMoving message display
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Characteristics of Embedded Systems - Dependability
• Reliability: R(t) = probability of system workingcorrectly provided that it was working at t=0
• Maintainability: M(d) = probability of systemworking correctly d time units after error occurred.
• Availability: probability of system working at time t
• Safety: no harm to be caused
• Security: confidential and authentic communication
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Characteristics of Embedded Systems-Efficiency
• Energy efficient
• Code-size efficient (especially for systems on a chip)
• Run-time efficient
• Weight efficient
• Cost efficient
• Dedicated user interface (no mouse, keyboard andscreen).
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Characteristics of Embedded Systems
• Many ES must meet real-time constraints:
• A real-time system must react to stimuli from the controlled object (or the operator) within the time interval.– For real-time systems, right answers arriving too
early or too late are wrong.
– An embedded system can be a• Hard real-time system
• Soft real-time system
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Hard real-time system
• In hard real-time systems the tasks should be run in on time , time is major constraints.
• The response time requirements of hard real-time systems are in the order of milliseconds or less and can result in a catastrophe if not met.
• Examples for hard real-time systems is– Missile – Industrial Automation– Automobiles– video transmission, each picture frame and audio
must be transferred at fixed rate
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Soft real-time system
• The response time requirements of soft real-time systems are higher and not very stringent.
• The soft real-time systems will slow down their response time if the load is very high
• Examples are
– DVD Player
– Mobile phones
– digital cameras
– playing robots
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Comparison
General Purpose Computing• Few applications that are
known at design-time.
• Not programmable by end user.
• Fixed run-time requirements (additional computing power not useful).
• Criteria:
– cost
– power consumption
• Broad class of applications.
• Programmable by end user.
• Faster is better.
• Criteria:– Cost
– average speed
Embedded Systems
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Features of Embedded system• Embedded Systems are the modern compacted
devices with multifunction capabilities.• An embedded system performs pre-defined tasks,
unlike a general-purpose personal computer.• An embedded system is a programmed hardware
device. A programmable hardware chip is theplatform and it is programmed with particularapplications.
• Embedded systems are not always standalonedevices. Many embedded systems consist of small,computerized parts within a larger device thatserves a more general purpose.
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Features of Embedded system
• The program instructions written for embedded systems are referred to as firmware,
• The program stored in read-only memory or Flash memory chips.
• They run with limited computer hardware resources: little memory, small or non-existent keyboard and/or screen.
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Embedded System Architecture
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development process of BASIC embedded System
1. Requirements (application)
2. Select microcontroller and H/W
3. Design hardware for your application
4. Write software
5.Write your HEX code to microcontroller
6. Test your proto type product
7. You start your product production
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Requirements
• Gather an informal description from the customers known as requirements.
• After getting enough information to begin designing the system architecture.
• Consumers of embedded systems are usually not embedded system designers.
• Example consider for designing washing machine
– Less power
– High efficiency
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Select microcontroller
• Select suitable microcontroller for required system design.
• Select special purpose processors if needed for the system like DSP processor
• We can classified like
– 8 bit microcontroller
– 16 bit microcontroller
– 32 bit microcontroller
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8 bit microcontroller
• It can perform 8 bit arithmetic and logical operations.
• Examples – 8051
– PIC16XX
• MB90890 Manufactured by Fujitsu .
• It performs all 16-bit Data operations
16 bit microcontroller
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•LPC2148 (ARM)Manufactured by
Philips.
•It performs all 32-bit as well as 16-
bit operations
32-bit Microcontroller
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Select Hardware
• Select required hardware components for the systems.
• Examples
– Transducers
– Reactors
– Communication protocols
– Input and Output interfaces
– ADCs
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Hardware's required for washing machine
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Hardware Design
• Design printed circuit board using some computer aided design tools
• Two steps are
– Design schematic
– Design corresponding layout
– Examples
• Orcad
• Proteous
• Express PCB
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Schematic diagram
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Layout format
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Software Design
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Developments Tools
• Assembler
• C compiler
• Editors
• RTOS (Real Time Operating System)
• Flash programmer
• Simulator
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Assembler
• It is a software that converts assembly
language program to Machine language
program understandable by microprocessor
MOV A,#CR
CALL PUTCHAR
MOV A,#LF
CALL PUTCHAR
RET
:10002600750B00750C00750D00750E007513FFD26B
:1000360083D284D282C287C286C285C281C200C2EE
:1000460001C202C203C204C205C206C20775140079
Assembly
program
Machine
Codes
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C cross Compiler
• It is a software that converts High level
language program [ written in C ] to Machine
language program understandable by
microprocessor
C program Machine Codes
main()
{ unsigned int d;
int_reg(); int_var();
for(d=0; d < 50000 ;d++)
{ LCD_PORT=0; }
init_lcd();
TR0=1;
uputs(0,0,15, "Conveyer System
"); 0,15," Version 1.0 "); P0=0;
P2=0;
:10002600750B00750C00750D00750E007513FFD26B
:1000360083D284D282C287C286C285C281C200C2EE
:1000460001C202C203C204C205C206C20775140079
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Editor
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What is Real-Time Operating System (RTOS)?
• real-time operating system (RTOS) is an operating system that guarantees to perform certain operation (task) within a specified time constraint.
• Software that manages the time of a microprocessor, microcontroller, or a digital signal processor
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Basic functions of RTOS
• Task scheduling
• Interrupt handling
• Memory management
• Task synchronization
• Avoid priority inversion
• Time management
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Types of RTOS
• Hard Real-time RTOS
– This type operating systems used in hard real-time embedded systems
– Examples are
• LynxOS
• OSE
• QNX
• RTLinux
• VxWorks
• Windows CE
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Types of RTOS
• Soft real-time operating system
– This type of operating systems used in soft real-time embedded systems
– Examples are
• uCOS-II
• Android
• embOS
• Symbian OS
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Flash programmer
• Flash programmer used to transfer the binary image from personal computer to embedded systems.
• Separate software are used for this purpose
• Examples are– Flash magic– Philips flash utility– Win pic– Tiny bootloader
PC
Embedded system
Programmer
RS232
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Test prototype product
• Multi meter
• Oscilloscope
• Logic Analyzer
• Terminal Emulation software
• Simulators & Emulators
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Features of PIC16F887A
• RISC architecture– Only 35 instructions to learn– All single-cycle instructions except branches
• Operating frequency 0-20 MHz• Precision internal oscillator
– Factory calibrated
• Power supply voltage 5V– Consumption: 220uA (4MHz), 11uA (32 KHz) 50nA
(stand-by mode)
• Power-Saving Sleep Mode
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Features Continue..
• Brown-out Reset (BOR) with software control option
• 33 input/output pins• 8K ROM memory in FLASH technology
– Chip can be reprogrammed up to 1,00,000 times
• In-Circuit Serial Programming Option– Chip can be programmed even embedded in the target
device
• 256 bytes EEPROM memory– Data can be written more than 1,0,00,000 times
• 368 bytes RAM memory
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Features Continue..
• A/D converter:– 14-channels– 10-bit resolution
• 3 independent timers/counters• Watch-dog timer• Analogue comparator module with
– Two analogue comparators– Fixed voltage reference (0.6V)– Programmable on-chip voltage reference
• PWM output steering control• Enhanced USART module
– Supports RS-485, RS-232 and LIN2.0– Auto-Baud Detect
• Master Synchronous Serial Port (MSSP)– supports SPI and I2C mode
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PIN Diagram
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Pin Description
• The most pins are multi-functional.• The fifth pin specifies the following functions
– RA3 Port A third digital input/output– AN3 Third analog input– Vref+ Positive voltage reference– C1IN+ Comparator C1positive input
• trick is often used because it makes the microcontroller package more compact without affecting its functionality.
• These various pin functions cannot be used simultaneously, but can be changed at any point during operation.
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Central Processor Unit (CPU)
• The CPU is manufactured with RISC technology
• The CPU can recognizes only 35 simpleinstructions (In order to program some othermicrocontrollers it is necessary to know morethan 200 instructions by heart).
• The execution time is the same for allinstructions except two.
• The Jump and Branch instructions execution timeis 2 instruction cycles.
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CPU Continues..
• if the microcontroller’s operating speed is20MHz, execution time of each instruction willbe 200nS, i.e. the program will be executed atthe speed of 5 million instructions per second!
• This microcontroller has three types ofmemory- ROM, RAM and EEPROM.
• ROM memory is used to permanently save theprogram being executed.
• This is why it is often called “programmemory”.
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ROM Memory
• The PIC16F887A has 8Kb of ROM (in total of8192 locations).
• This ROM is made with FLASH technology
• Its contents can be changed by providing aspecial programming voltage (13V).
• The program is stored to ICs using simpleelectronic device called the Programmer.
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ROM Memory Concept
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EEPROM Memory
• Similar to program memory, the contents of EEPROM is permanently saved, even the power goes off.
• However, unlike ROM, the contents of the EEPROM can be changed during operation of the microcontroller.
• That is why this memory (256 locations) is a perfect one for permanently saving results created and used during the operation.
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RAM Memory
• RAM Memory consists of two parts: – general-purpose registers
– special-function registers (SFR).
• both groups of registers are cleared when power goes off.
• Their functions do not have many things in common.
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General-Purpose Registers• General-Purpose registers are used for storing
temporary data and results created during operation.
• It is necessary to specify the address of some general purpose register and assign it a new function.
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SFR Registers• Special-Function registers are also RAM memory
locations.• their purpose is predetermined during
manufacturing process and cannot be changed.• Since their bits are physically connected to particular
circuits on the chip.• Any change of their contents directly affects the
operation of the microcontroller or some of itscircuits.
• For example, by changing the TRISA register, thefunction of each port A pin can be changed in a wayit acts as input or output.
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SFR Registers Continues..
• high-level programming language can use the list of all registers with their exact addresses, it is enough to specify the register’s name in order to read or change its contents.
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RAM Memory Banks
• The data memory is partitioned into four banks.• Prior to accessing some register during program
writing (in order to read or change its contents),it is necessary to select the bank which containsthat register.
• Two bits of the STATUS register are used for bankselecting.
• the most commonly used SFRs have the sameaddress in all banks which enables them to beeasily accessed.
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STACK
• A part of the RAM used for the stack consists of eight13-bit registers.
• Before the microcontroller starts to execute asubroutine (CALL instruction) or when an interruptoccurs, the address of first next instruction beingcurrently executed is pushed onto the stack, i.e. ontoone of its registers.
• In that way, upon subroutine or interrupt execution, themicrocontroller knows from where to continue regularprogram execution.
• This address is cleared upon return to the mainprogram because there is no need to save it any longer
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Interrupt System
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SFR Registers Continues..
• The special function registers can be classified into two categories:
– Core (CPU) registers.
• control and monitor operation and processes in the central processor.
– Peripheral SFRs
• control the operation of peripheral units (serial communication module, A/D converter etc.).
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STATUS Register
RP1 RP0 Active Bank
0 0 Bank0
0 1 Bank1
1 0 Bank2
1 1 Bank3
1 - Banks 0 and 1 are active (memory location 00h-FFh)0 - Banks 2 and 3 are active (memory location 100h-1FFh)
•RP1,RP0 - Bits select register bank. They are used for direct addressing.
IRP - Bit selects register bank. It is used for
indirect addressing.
1 - Banks 0 and 1 are active (memory
location 00h-FFh)
0 - Banks 2 and 3 are active (memory
location 100h-1FFh)
RP1,RP0 - Bits select register bank. They
are used for direct addressing.
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PRACTICAL SESSION
• Port programming
• Seven Segment
• LCD
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