Post on 01-Nov-2014
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WELCOME
EVERYBODY
MEMBERS FOR THE PRESENTAION
• NEHAL NAIK• DEVDATT NAIK• VIKAS NAIK
I/O TECHNIQUES & ITS TYPES
INTRODUCTION
• Users interact with the computer system through Input and Output (I/O) devices such as keyboard, mouse, monitor and so on. I/O devices are also called peripherals.
• I/O devices are used to exchange information between user and CPU. An I/O organization includes two major components namely I/O devices, I/O module. In addition it uses different techniques to exchange information namely programmed I/O, Interrupt I/O and Direct Memory Access (DMA).
I/O TECHNIQUES
• It is the technique of communication between memory and I/O devices. I/O techniques are categorized in three types based on how information is transfers between memory and I/O devices that whether it is using CPU interaction or Interrupt interaction.
TECHNIQUES OF I/O• Programmed I/O : The CPU issues a command then waits for I/O
operations to be complete. The CPU is faster than the I/O module then method is wasteful.
• Interrupt Driven I/O : The CPU issues commands then proceeds with its normal work until interrupted by I/O device on completion of its work.
• DMA : In this CPU and I/O Module exchange data without involvement of CPU.
• Memory mapped I/O : Memory and I/O are treated as memory only. It means no signal like IO/M.
• Isolated I/O : Address space of memory and I/O is isolated. It uses IO/M signal.
Three I/o Techniques
Four design techniques Multiple Interrupt Lines : In this method we have multiple
lines like in IC 8085. Software Polling : ISR polls to find out the device which has
interrupted. The CPU reads a status register.The method is time consuming.
Daisy Chin : The method is hardware polling. The ack signal propagates through and is stopped by the device who is interrupted.
Bus Arbitration : In this method the device first gets control of bus and then raises an interrupt request for data transfer. The CPU issues an ack then the devices gives vector for branching
I/O Steps
• CPU checks I/O module device status• I/O module returns status• If ready, CPU requests data transfer• I/O module gets data from device• I/O module transfers data to CPU• Variations for output, DMA, etc.
I/O Commands
CPU issues address› Identifies module (& device if >1 per module)
CPU issues command› Control - telling module what to do
e.g. spin up disk
› Test - check status e.g. power? Error?
› Read/Write Module transfers data via buffer from/to device
Addressing I/O Devices
• Under programmed I/O data transfer is very like memory access (CPU viewpoint)
• Each device given unique identifier• CPU commands contain identifier (address)
I/O Mapping
• Memory mapped I/O– Devices and memory share an address space– I/O looks just like memory read/write– No special commands for I/O
• Large selection of memory access commands available
• Isolated I/O– Separate address spaces– Need I/O or memory select lines– Special commands for I/O
• Limited set
I/O Module
I/O module is intermediate between I/O devices and CPU. System buses are connected to the one end of I/O module and other end is connected to the number of I/O devices. It used to exchange information between I/O devices and CPU. I/O
devices cannot be directly connected to the system buses; they are connected to the system buses
through module.
I/O Module Diagram
Data Register
Status/Control Register
ExternalDeviceInterfaceLogic
ExternalDeviceInterfaceLogic
InputOutputLogic
DataLines
AddressLines
DataLines
Data
Status
Control
Data
Status
Control
Systems Bus Interface External Device Interface
Functions of I/O ModuleThe major functions of modules are categorized as
follows1.Control and Timing - In some of the I/O
operation few resources shared such as CPU and memory because CPU communicates with more
than one device at a time.2.Processor Communication - I/O module
communicates with the CPU and I/O devices
Features of I/O Module
• Data Buffering - As I/O devices are much slower than CPU and memory. In order to maintain speed of data flow between I/O devices and internal resources, I/O module buffers data.
• Error Detection - It is built- in feature of I/O module that detects electrical and mechanical errors.
INPUT/OUTPUT MODULE STRUCTURE
Control and Timing
• CPU asks I/O module to check the status of attached device.
• I/O module tells the status. • CPU requests for data transfer to I/O module if
device is ready. • I/O module gathers the data and transfers to
the CPU.
Interrupts
• CPU interrupt request line triggered by I/O devices• Interrupt handler receives interrupt• Maskable to ignore or delay some interrupts• Interrupt vector to dispatch interrupt to correct handler• Based on priorty• Some unmaskable• Interrupt mechanism also used for exceptions
Interrupt Processing
Multiple interrupts
• The techniques above not only identify the requesting I/O module but provide
• methods of assigning priorities• Multiple lines – processor picks line with highest
priority• Software polling – polling order determines priority• Daisy chain – daisy chain order of the modules
determines priority• Bus arbitration – arbitration scheme determines
priority
Interrupt Driven I/O
• Overcomes CPU waiting• No repeated CPU checking of device• I/O module interrupts when ready
Conclusions
• Designing dependable I/O systems has two aspects: individual I/O and redundancy. The design of dependable individual I/O has a variety of aspects including EMC, shock/vibration, environment, A/D and D/A conversion, diagnostics, testing and calibration. Each can present special challenges for the embedded designer in terms of cost or accessibility concerns. All of the redundancy methods, including diversity, interlocks, and human interaction, should be considered to address the safety concerns of an embedded system.
• Two new trends in I/O design are important: Fieldbus and Intelligent I/O. These promise increased functionality and lower cost. The primary challenge to acceptance of these techniques is standardization to achieve interoperability.
• The embedded I/O designer must be well versed in a variety of techniques to produce dependable cost effective designs.
THANK YOU EVERYBODY