Intel 8080 manual

Page 39

The input level specification impl ies that any semi- conductor memory or I/O device connected to the 8080 Data Bus must be able to provide a minimum of

3.3volts in its high state. Most semiconductor mem- ories and standard TTL I/O devices have an output capability of between 2.0 and 2.8 volts, obviously a direct connection onto the 8080 Data Bus would re- quire pullup resistors, whose value should not affect the bus speed or stress the drive capability of the memory or I/O components.

The 80S0A output drive capability (lOl) 1.9mA max. is sufficient for small systems where Memory size and I/O requirements are minimal and the entire system is contained on a single printed circuit board. Most sys- tems however, take advantage of the high-perfor- mance computing power of the 8080 CPU and thus a more typical system would require some form of buf- fering on the 80S0 Data Bus to support a larger array of Memory and I/O devices which are likely to be on separate boards.

A device specifically designed to do this buffering function is the INTEL® 8216, a (4) four bit bi-direc- tional bus driver whose input voltage level is compat- ible with standard TTL devices and semiconductor memory components, and has output drive capability of 50 mAo At the 8080 side, the 8216 has a "high" output of 3.65 volts that not only meets the S080 input spec but provides the designer with a worse case 350 mV noise margin.

A pair of S216's are connected directly to the 8080 Data Bus (07-00) as shown in figure 3-5. Note that the OBI N signal from the 8080 is connected to the direction control input (01 EN) so the correct flow of data on the bus is maintained. The chip select (CS) of

the S216 is connected to BUS ENABLE (BUSEN) to allow for DMA activities by deselecting the Data Bus Buffer and forcing the outputs of the S216's into their high impedance (3-state) mode. This allows other devices to gain access to the data bus (DMA).

System Control Logic Design

The Control Bus maintains discipline of the bi-direc- tional Data Bus, that is, it determines what type of device will have access to the bus (Memory or I/O) and generates signals to assure that these devices transfer Data with the SOSO CPU within the proper timing "windows" as dictated by the CPU operational characteristics.

As described previously, the 8080 issues Status infor- mation at the beginning of each Machine Cycle on its Data Bus to indicate what operation will take place during that cycle. A simple (8) bit latch, like an INTEL® 8212, connected directly to the 80S0 Data Bus (07-00) as shown in figure 3-5 will store the

Status information. The signal that loads the data into the Status Latch comes from the Clock Gener- ator, it is Status Strobe (STSTB) and occurs at the start of each Machine Cycle.

Note that the Status Latch is connected onto the SOSO Data Bus (07-00) before the Bus Buffer. This is to maintain the integrity of the Data Bus and simplify Control Bus timing in DMA dependent environments..

As shown in the diagram, a simple gating of the out- puts of the Status Latch with the DB INand WR signals from the S080 generate the (4) four Control signals that make up the basic Control Bus.

These four signals: 1. Memory Read (MEM R)

2.Memory Write (MEM W)

3.I/O Read (I/O R)

4.I/O Write (I/O W)

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connect directly to the MCS-80 component "family" of ROMs, RAMs and I/O devices.

A fifth signal, Interrupt Acknowledge (lNTA) is added to the Control Bus by gating data off the Status Latch with the DBIN signal from the S080 CPU. This signal is used to enable the Interrupt Instruction Port wh ich holds the RST instruction onto the Data Bus.

Other signals that are part of the Control Bus such as WO, Stack and M1 are present to aid in the testing of the System and also to simplify interfacing the CPU to dynamic memories or very large systems that re- quire several levels of bus buffering.

Address Buffer Design

The Address Bus (A 15-AO) of the 8080, like the Data Bus, is sufficient to support a small system that has a moderate size Memory and I/O structure, confined to a single card. To expand the size of the system that the Address Bus can support a simple buffer can be added, as shown in figure 3-6. The INTEL®S212 or 8216 is an excellent device for this function. They provide low input loading (.25 mA), high output drive and insert a minimal delay in the System Timing.

Note that BUS ENABLE (BUSEN) is connected to the buffers so that they are forced into their high- impedance (3-state) mode during DMA activities so that other devices can gain access to the Address Bus.

3-5

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Contents Page Programmable Peripheral Interface Clock Generator for 8080ASystem Controller for 8080A Programmable Communication InterfaceContents 127 Peri pheralsChapter Packaging Information Page Advantages of Designing With Microcomputers Microcomputer Design AidsConventional System Programmed Logic Applications Example Iii1IIII~Iff1 Peripheral Devices Encountered ApplicationTypical Computer System Architecture of a CPUAccumulator Instruction Register and Decoder Program Counter Jumps, Subroutines and the StackComputer Operations Control CircuitryAddress Registers Arithmetic/Logic Unit ALUWait memory synchronization Instruction FetchMemory Read Memory WritePage Page 8080 Photomicrograph With Pin Designations INTE~Registers Architecture of the 8080 CPUProcessor Cycle Arithmetic and Logic Unit ALUInstruction Register and Control Data Bus BufferMachine Cycle Identification Halt State Transition SequenceStatus Word Chart Status Bit DefinitionsStatus Information Definition ?~~ CPU State Transition DiagramRr\ ONE ,----- ~ ~2. State Definitions State Associated ActivitiesInterrupt Sequences RLrL- rL rL rL-rL- rLrL¢2 -+--sLJJlL-..rrL~LJLLJTLJJ\.lJL Hold Sequences Halt SequencesSTART-UP of the 8080 CPU 11. Halt Timing ~~~~t==p 001 STATUS6 Xram ~iA~~~11 ~iA~~~11~iA~~ll,12 ~A~~~ll111 000 001 010 011 100 101 ValueBasic System Operation Typical Computer System Block DiagramClock Generator Design CPU Module Design8080 CPU Clock Generator and High Level DriverClK 0.......-..-.-----.. tf1A TTL ~50nsHigh Level Driver Design Ststb !1 Page Interfacing the 8080 CPU to Memory and I/O Devices ROM InterfaceRAM Interface Ill Memory Mapped I/O InterfaceGeneral Theory Isolated I/OAddressing Interface ExampleMemr to 15 Format 13 Format8080 Instruction SET Instruction and Data FormatsAddressing Modes Byte OneByte Two Byte Three I D7All Symbols and AbbreviationsSymbols Meaning Description FormatReg. indirect Content of register r2 is moved to register r1Data Transfer Group MOV r1, r2 Move Register0 I R 0 I R p0 I 0 o 0 IArithmetic Group 1 I0 I D I D R 0 ICycles States Addressing reg. indirect Flags Z,S,P ,CY,AC I ILogical Group OCR M Decrement memory1 1 1 I 0 I 1 I 1 II 1 I 1 o I 1 I 1 I ~11~Cycles States Flags none 0 I 1 I0 I 0 1 I 0 I 0 I000 Branch GroupI c c I c I 0 I 0 I Ccondition addrSP ~ SP + 1 I R Stack, I/O, and Machine Control GroupI 1 o Push rpCycles States Flags None Exchange stack top with Hand L~ SP + ~ dataInstruction SET Programmable Peripheral Interface 8224 8080A-1 8228 8080A-2 8080A M8080-A Page PIN Names Schottky BipolarClock Generator Functional DescriptionGeneral OscillatorStstb Status Strobe Power-On Reset and Ready Flip-FlopsCrystal Requirements Characteristics8pF InputTORS tORH tOR FMAX Characteristics For tCY = 488.28 nsExample T42 T01 T02 T03 TossDbin PIN Configuration Block DiagramBlock GeneralInta None Control SignalsHlda to Read Status Outputs Characteristics TA = Oc to 70C Vee = 5V ±5%TE~r WaveformsVCC=5V GoUTStstb VTHGND ---. r ·-c?oo .H Intel Silicon Gate MOS 8080 aVee Vss8080A Functional PIN Definition IOl = 1.9mA on all outputs CharacteristicsAbsolute Maximum RATINGS· Capacitance~~1 t CY =..... -r-DATAIN~I~~~ Timing WaveformsTypical ~ Output Delay VS. a Capacitance CharacteristicsTypical Instructions Instruction SETSummary of Processor Instructions Silicon Gate MOS 8080.AInfel Silicon Gate MOS 8080A-1 Symbol Parameter Typ MaxUnit Fft~l ~tOF.I~-t TYPICAL!J. Output Delay VS. ~ Capacitance Infel Silicon Gate MOS 8080 A-2 VAOOR/OATA = VSS + O.45V +10Cout J1AUnit Test Condition Symbol Parameter MinMin. Max. Unit Test Condition Typical ~ Output Delay VS. ~ CapacitancePage Intel . Silicon Gate MOS M8080A Interrupt instructions Immediate mode or I/O instructionsRegister to regist~r, memory refer Ence, arithmetic or logical, rotateLlf17 Summary of Processor InstructionsM8080A Functional PIN Definition Silicon Gate MOS M8080AAbsolute Maximum Ratings IOL = 1.9mA on all outputsOperation Symbol Parameter Min. Max Unit Test Condition ~I~ Silicon Gate MOS M8080APage ROMs 8702A 8704 8708 8316A Page Silicon Gate MOS 8702A Operating Characteristics PIN ConnectionsVoo = V ce Switching Characteristics1N= Vee ~10%Cs=o.~ \ \SYMBOLTESTMIN. TYP. MAX. Unit Conditions Operating Characteristics for Programming OperationSymbol Test Characteristics for Programming OperationProgram Operation Switching Characteristics for Programming OperationCS = OV Programming Operation of the 8702AProgramming Instructions for the 8702A Operation of the 8702A in Program ModeII. Programming of the 8702A Using Intel Microcomputers III a Erasing ProcedurePage PIN Names PIN Configurations Block DiagramVOH1 CommentIII IBBMax Unit Symbol Parameter Typ. Max. Unit ConditionsTest Conditions WaveformsParameter Min TpF Program Pulse Fall TimeProgramming Current RnA Program Pulse Amplitude Read/Program/Read Transitions CS/WE = +12V+-------1 PEEEf!1EJEZPlEzz$m=2!·m·· Icc 150 rSilicon Gate MOS Outa CommentMAX Unit CS=O.O~~~H --4!~--~N-~-TA-AL-~-DU-T--~\ 100 ns 7001 JJ.s200ns 500ns 300 ns Cs .. o.~ ~r Typical CharacteristicsSilicon Gate MOS ILO IlclIlpc IlkcConditions of Test for Characteristics CoUTCIN ~ ~ ~ Customer Number Oate Mask Option SpecificationsMarking Pppp79-80 ~ r ------ + -- t --- . L . ------ rJTitle Card BlankIntel Silicon Gate MOS ROM 8316A PIN Configuration Block Diagram400 Conditions of Test forCAPACITANCE2 TA = 25C, f = 1 MHz Waveforms OU~TVALIDILICO.N Gate MOS ROM 8316A Typical D.C. CharacteristicsMask Option Speci Fications CustomerNumber Oate STOCOM~ANY Name Title CardRAMs Page Silicon Gate MOS PIN Configuration Logic Symbol Block Diagram+----+ ~E~~=~utP~-t-·7~igh-~\/oltage-~------ ---- --i2-+---=~== ~== OC 10H = -150 p.A00 ~ Conditions of TestPage Silicon Gate MOS PIN Configuration Logic Symbol Block DiagramICC2 Symbol Parameter Min. Typ.rIII ICC1Timing Measurement Reference Level Volt Write 1~-tAW--.I-----I550 200 Input Pulse Rise and Fall Times 20nsecPage Silicon Gate MOS TA = OOC to +70C, Vee = 5V ±5% unless otherwise specified Power Dissipation Watt5V to +7V CommentConditions of Test 85o-·-···T+--~~~TL~~~EEt~~~P-.± Capacitance T a = 25C, f = 1MHz~~~b~.J Typical A.C. CharacteristicsSilicon Gate MOS 8102A-4 TA = OC to +70 o e, Vcc = 5V ±5% unless otherwise specified 450 230300 Output Source Current VS VIN Limits VS. TemperatureAccess Time VS Ambient Temperature Access Time VS LOAD·CAPACITANCEPIN Configuration Logic Symbol Block Diagram Fully Decoded Random Access BIT Dynamic MemoryIOOAV2 Silicon Gate MOS 81078·4IMP~ri~~CE II.~Write Cycle Read Cycle4000 Ref =Typical Characteristics Symbol Parameter Min Max RWc 590 CDNumbers in parentheses are for minimum cycle timing in ns System Interfaces and Filtering Power DissipationStandby Power RefreshTypical System BIT 256 x 4 Static Cmos RAM Icccr ICC2VIH VOL VOH VORTiming Measurement Reference Level Volt Input Pulse Rise and Fall Times 20nsec~I----- t CW2 ------ . t Schottky Bipolar PIN Configuration Logic SymbolVoo- --- ---T Conditions of TestAll driver outputs are in the state indicated Power Supply Current Drain and Power DissipationTypical System Dynamic Memory Refresh Controller Page 8212 8255 8251 Page EIGHT-BIT INPUT/OUTPUT Port PIN Configuration Logic DiagramOS2 Functional DescriptionGated Buffer Basic Schematic SymbolsII. Gated Buffer 3·STATE Are 3-stateBI-DIRECTIONAL BUS Driver III. Bi-Directional Bus DriverIV. Interrupting Input Port Interrupt Instruction PortOvJ \.. -4~ VI. Output Port With Hand-ShakingVII Status Latch 8080 4System Viii SystemOUT VeeIX System 1G~D L-~ DalN-t?!NrJAbsolute Maximum Ratings· Characteristics052 ~ Typical CharacteristicsTpw OUTSwitching Characteristics TA = OC to + 75C Vee = +5V ± 5%12 pF ~~~lEI~S 1-- +SV Programmable Peripheral InterfaceBasic Functional Description GeneralData Bus Buffer Read/Write and Control LogicPorts A, B, and C ResetPIN Configuration Group a and Group B ControlsPA 7 ·pAo Mode SelectionSingle Bit Set/Reset Feature Detailed Operational DescriptionOperating Modes Mode 0 Basic Input/Output Mode 0 TimingInterrupt Control Functions Mode 0 Configurations Mode 0 Port Definition Chart119 · / ,4 Operating Modes Mode 1 Strobed Input/OutputInte a Input Control Signal DefinitionIBF Input Buffer Full F/F Intr Interrupt RequestIntea Output Control Signal DefinitionOutput Operations Combinations of ModeBi-Directional Bus I/O Control Signal Definition Operating ModesMode 2 Bi-directional Timing Mode 2 Control WordMode 2 and Mode 0 Output Mode 2 CombinationsReading Port C Status Special Mode Combination ConsiderationsMode Definition Summary Table Source Current Capability on Port B and Port CKeyboard and Terminal Address Interface ApplicationsPrinter Interface Keyboard and Display Interface~.LEFT/RIGHT PCOSilicon Gate MOS Time From STB = 0 To IBF Characteristics TA = oc to 70C Vee = +5V ±5% vss = OVVil Input Low Voltage Input High Voltage Val Output Low Voltage IOl = 1.6mAMode 0 Basic Input Mode 1 Strobed Input Mode 2 Bi-directional Page Programmable Communication Interface ClK Clock Reset ResetGeneral ReadlWrite Control logicDTR Data Termin·al Ready Modem ControlDSR Data Set Ready TxE Transmitter EmptyRxC Receiver Clock Receiver BufferReceiver Control RxRDY Receiver ReadyProgramming Mode InstructionCommand Instruction Detailed Operation DescriptionData C~~RACTER Mode Instruction DefinitionAsynchronous Mode Transmission Asynchronous Mode ReceiveSynchronous Mode, Transmission Format Synchronous Mode TransmissionSynchronous Mode Receive Mode Instruction Format, Synchronous ModeStatus Read Format Command Instruction DefinitionCommand Instruction Format Status Read DefinitionSynchronous Interface to Telephone Lines Asynchronous Serial Interface to CRT Terminal, DC-9600 BaudAsynchronous Interface to Telephone Lines Synchronous Interface to Terminal or Peripheral DeviceCapacitance IccIOL Typ TA = oc to 70C VCC = 5.0V ±5% Vss = OV Symbol ParameterRXD~ RxDSRX ~4IlI ~AST BIT ,----1Peripherals Page High Speed 1 OUT of 8 Binary Decoder Enable Gate DecoderSystem 24K Memory Interface Using a very similar circuit to the I/O port decoder, an arPort Decoder Chip Select DecoderIll Logic Element Example\lJ JJ,.--+-I----.....18205 Characteristics TA = OOC to +75C, Vee = 5.0V ±5%Typical Characteristics Symbol VOL VOHTest Waveforms Switching Characteristics Conditions of Test Test LoadAddress or Enable to Output Delay VS. Load Capacitance Address or Enable to Output Delay VS. Ambient TemperaturePIN Configuration ~ R~ ~ Interrupts in Microcomputer Systems Polled MethodInterrupt Method Current Status Register Priority EncoderAO, A1, A2 Control SignalsINTE, elK ElR, ETlG, ENGlBasic Operation Level ControllerLevel Controller I ICascading Absolute Maximum Ratings Operating CharacteristicsSymbol Parameter Limits Unit Conditions Min Typ.£1 LosCharacteristics and Waveforms TA = oc to +70C, vcc = +5V ±5% Schottky Bipolar 8216 8226 +-......---- n csControl Gating OlEN, CS Bi-Directional DriverApplications of 8216/8226 Memory and 1/0 Interface to a Bi-directional BusLarge microcomputer systems it is often necessary to pro Input Leakage Current OlEN, CS VR =5.25V IcC Power Supply Current 120Input Load Current OlEN, CS VF =0.45 Input Load Current All Other Inputs VF =0.45OUT WaveformsPage 8253 8257 8259 Page It uses nMOS technology ~Jmodesof operation are Programmable Interval TimerSystem Interface Block DiagramPreliminary Functional Description System InterfaceProgrammable DMA Controller System Interface Dack 2System Application CS-------It LJJ Intel CPU GroupROMs RAMs Peripheral Coming Soon~~~1 735~It-j Lead CerDIP Dual IN-LINE Package D \.--.J.. ~~~l·34o~ Lead Plastic Dual IN-LINE Package PSales and Marketing Offices Distributors Page Page Page Page Page Page Instruction SET Summary of Processor Instructions By Alphabetical Order Instruction SETMicrocomputer System Users Registration Card Microcomputer Systems Bowers Avenue Santa Clara, CA Intel CorporationInter
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8080 specifications

The Intel 8085 and 8080 microprocessors were groundbreaking innovations in the world of computing, paving the way for future microprocessor development and personal computing.

The Intel 8080, introduced in 1974, was an 8-bit microprocessor that played a fundamental role in the early days of personal computing. With a 16-bit address bus, it had the capability to address 64 KB of memory. Running at clock speeds of 2 MHz, the 8080 was notable for its instruction set, which included 78 instructions and 246 opcodes. It supported a range of addressing modes including direct, indirect, and register addressing. The 8080 was compatible with a variety of peripherals and played a crucial role in the development of many early computers.

The microprocessor's architecture was based on a simple and efficient design, making it accessible for hobbyists and engineers alike. It included an 8-bit accumulator, which allowed for data manipulation and storage during processing. Additionally, the 8080 featured registers like the program counter and stack pointer, which facilitated program flow control and data management. Its ability to handle interrupts also made it suitable for multitasking applications.

The Intel 8085, introduced in 1976, was an enhancement of the 8080 microprocessor. It maintained a similar architecture but included several key improvements. Notably, the 8085 had a built-in clock oscillator, simplifying system design by eliminating the need for external clock circuitry. It also featured a 5-bit control signal for status line management, which allowed for more flexible interfacing with peripheral devices. The 8085 was capable of running at speeds of up to 3 MHz and had an extended instruction set with 74 instructions.

One of the standout features of the 8085 was its support for 5 extra instructions for stack manipulation and I/O operations, which optimized the programming process. Additionally, it supported serial communication, making it suitable for interfacing with external devices. Its 16-bit address bus retained the 64 KB memory addressing capability of its predecessor.

Both the 8080 and 8085 microprocessors laid the groundwork for more advanced microprocessors in the years that followed. They demonstrated the potential of integrated circuits in computing and influenced the design and architecture of subsequent Intel microprocessors. Their legacy endures in the way they revolutionized computing, making technology accessible to a broader audience, and their influence is still felt in the design and architecture of modern microprocessors today.