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MSM82C59A-2RS

MSM82C59A-2RS

  • 厂商:

    OKI

  • 封装:

  • 描述:

    MSM82C59A-2RS - PROGRAMMABLE INTERRUPT CONTROLLER - OKI electronic componets

  • 数据手册
  • 价格&库存
MSM82C59A-2RS 数据手册
E2O0021-27-X3 ¡ Semiconductor MSM82C59A-2RS/GS/JS ¡ Semiconductor PROGRAMMABLE INTERRUPT CONTROLLER This version: Jan. 1998 MSM82C59A-2RS/GS/JS Previous version: Aug. 1996 GENERAL DESCRIPTION The MSM82C59A-2 is a programmable interrupt for use in MSM80C85AH and MSM80C86A10/88A-10 microcomputer systems. Based on CMOS silicon gate technology, this device features an extremely low standby current of 100mA (max.) in chip non-selective status. During interrupt control status, the power consumption is very low with only 5 mA (max.) being required. Internally, the MSM82C59A-2 can control priority interrupts up to 8 levels, and can be expanded up to 64 levels by cascade connection of a number of devices. FEATURES • Silicon gate CMOS technology for high speed and low power consumption • 3 V to 6 V single power supply • MSM80C85AH system compatibility (MAX5 MHz) • MSM80C86A-10/88A-10 system compatibility (MAX8 MHz) • 8-level priority interrupt control • Interrupt levels expandable up to 64 levels • Programmable interrupt mode • Maskable interrupt • Automatically generated CALL code (85 mode) • TTL compatible • 28-pin Plastic DIP (DIP28-P-600-2.54): (Product name: MSM82C59A-2RS) • 28-pin Plastic QFJ (QFJ28-P-S450-1.27): (Product name: MSM82C59A-2JS) • 32-pin Plastic SSOP (SSOP32-P-430-1.00-K): (Product name: MSM82C59A-2GS-K) 1/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS BLOCK DIAGRAM INTA INT D7 - D0 Data Bus Buffer Control Logic RD WR A0 CS Read/ Write Logic InService Register (ISR) Priority Resolver Interrupt Request Register (IRR) IR0 IR1 IR2 IR3 IR4 IR5 IR6 IR7 CAS0 CAS1 CAS2 SP/EN Cascade Buffer/ Comparator Interrupt Mask Register (IMR) Internal Bus (8 bits) MSM82C59A-2 Internal Block Diagram 2/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS PIN CONFIGURATION (TOP VIEW) 32 pin Plastic SSOP 28 pin Plastic DIP CS WR RD D7 D6 D5 D4 D3 D2 D1 D0 CAS0 CAS1 GND 1 2 3 4 5 6 7 8 9 10 11 12 13 14 28 27 26 25 24 23 22 21 20 19 18 17 16 15 VCC AO INTA IR7 IR6 IR5 IR4 IR3 IR2 IR1 IR0 INT SP/EN CAS2 CS WR RD NC D7 D6 D5 D4 D3 D2 D1 D0 NC CAS0 CAS1 GND 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 32 31 30 29 28 27 26 25 24 23 22 21 20 19 18 17 VCC AO INTA NC IR7 IR6 IR5 IR4 IR3 IR2 IR1 IR0 NC INT SP/EN CAS2 28 pin Plastic QFJ 28 VCC D6 5 D5 6 D4 7 D3 8 D2 9 D1 10 D0 11 GND 14 SP/EN 16 CAS0 12 CAS1 13 CAS2 15 INT 17 IR0 18 26 INTA 2 WR 3 RD 1 CS 27 A0 4 D7 25 IR7 24 IR6 23 IR5 22 IR4 21 IR3 20 IR2 19 IR1 3/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS ABSOLUTE MAXIMUM RATINGS Parameter Power Supply Voltage Input Voltage Output Voltage Storage Temperature Power Dissipation Symbol VCC VIN VOUT TSTG PD Conditions Respect to GND — Ta = 25°C 0.9 Rating MSM82C59A-2RS MSM82C59A-2GS MSM82C59A-2JS Unit V V V °C 0.9 W –0.5 - +7 –0.5 - VCC +0.5 –0.5 - VCC +0.5 –55 - +150 0.7 OPERATING RANGES Parameter Power Supply voltage Operating Temperature Symbol VCC TOP Range 3-6 –40 - +85 Unit V °C RECOMMENDED OPERATING CONDITIONS Parameter Power Supply Voltage Operating Temperature "L" Lebel Input Voltage "H" Lebel Input Voltage Symbol VCC TOP VIL VIH Min. 4.5 -40 -0.5 2.2 Typ. 5 +25 — — Max. 5.5 +85 +0.8 VCC +0.5 Unit V °C V V DC CHARACTERISTICS Parameter "L" Level Output Voltage "H" Level Output Voltage Input Leak Current IR Input Leak Current Output Leak Current Standby Power Supply Current Average Operation Power Supply Current Symbol VOL VOH ILI ILIR ILO ICCS IOL = 2.5 mA IOH = –2.5 mA IOH = –100 mA 0 £ VIN £ VCC 0 £ VOUT £ VCC CS = VCC, IR = VCC VIL = 0 V, VIH = VCC VIN = 0 V/VCC CL = 0 pF VCC = 4.5 V - 5.5 V Ta = –40°C - +85°C Conditions Min. — 3.0 VCC –0.4 –1 –300 –10 — Typ. — — — — — — 0.1 Max. 0.4 — — 1 10 10 100 Unit V V mA mA mA mA ICC — 5 mA 4/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS AC CHARACTERISTICS Ta = –40°C - +85°C, VCC = 5 V ± 10% Parameter Address Setup Time (to RD) Address Hold Time (after RD) RD/INTA Pulse Width Address Setup Time (to WR) Address Hold Time (after WR) WR Pulse Width Data Setup Time (to WR) Data Hold Time (after WR) IR Input Width(Low) CAS Input Setup Time (to INTA) (Slave) End of RD to Next RD End of INTA to Next INTA End of WR to Next WR End of Command to Next Command Data Valid Following RD/ INTA Data Floating Following RD/ INTA INT Output Delay Time CAS Valid Following 1 st. INTA (master) EN Active Following RD/INTA EN Inactive Following RD/ INTA Data Valid after Address Data Valid after CAS Symbol tAHRL tRHAX tRLRH tAHWL tWHAX tWLWH tDVWH tWHDX tJLJH tCVIAL tRHRL tWHWL tCHCL tRLDV tRHDZ tJHIH tIALCV tRLEL tRHEH tAHDV tCVDV Min. 10 5 160 0 0 190 160 0 100 40 160 190 400 — 10 — — — — — — Max. — — — — — — — — — — — — — 120 85 300 360 100 150 200 200 Unit ns ns ns ns — ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns ns 1 2 1 1 1 1 1 1 — Other timing — INTA sequence — Write timing — Read INTA timing TEST Conditions Delay times AC Test Circuits V1 Output from Device under Test R1 Test Point R2 C1* A.C. Testing Input, Output Waveform Input VIH+0.4 V 1.5V VIL–0.4 V Output VOH 1.5 V VOL A. C. Testing: All input signals must switch between VIL–0.4 V and VIH+0.4 V. TR and TF must be less than of equal to 15 ns. * Includes Stray and Jig Capacitance Test Condition Definition Table Test Condition 1 2 V1 R1 R2 C1 1.7 V 523 W Open 100 pF 4.5 V 1.8k W 1.8k W 30 pF 5/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS TIMING CHART Write Timing WR tWLWH tAHWL CS Address Bus A0 tDVWH Data Bus tWHAX tWHDX Read/INTA Timing RD/INTA tRLRH EN tRLEL tRHEH CS Address Bus A0 tAHRL tRHAX tRLDV tAHDV Data Bus tRHDZ Other Timing RD/INTA tRHRL WR tWHWL RD/INTA/WR tCHCL RD/INTA/WR 6/28 ¡ Semiconductor INTA Sequence (85 mode) IR MSM82C59A-2RS/GS/JS tJHIH tJLJH INT INTA Data Bus tCVIAL tCVDV CAS Address Bus tIALCV INTA Sequence (86 mode) IR INT INTA Data Bus CAS Address Bus 7/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS PIN FUNCTION DESCRIPTION Pin Symbol D 7 - D0 Name Bidirectional Data Bus Input/Output Input/Output Function This 3-state 8-bit bidirectional data bus is used in reading status registers and writing command words through the RD/WR signal from the CPU, and also in reading the CALL instruction code by the INTA signal from the CPU. Data transfer with the CPU is enabled by RD/WR when this pin is at low level. The data bus (D0 thru D7) is switched to high impedance when the pin is at high level. Note that CS does not effect INTA. Data is transferred from the MSM82C59A-2 to the CPU when this pin is at low level. IRR (Interrupt Request Register), ISR (In-Service Register), IMR (Interrupt Mask Register), or a Poll word is selected by OCW3 and A0. Commands are transferred from the CPU to the MSM82C59A-2 when this pin is at low level. This pin is used together with the CS, WR, and RD signals to write commands in the command registers, and to select and read status registers. This is normally connected to the least significant bit of the address bus. (A0 for MSM80C85AH, A1 for MSM80C86A-10/88A-10). These pins are outputs when the MSM82C59A-2 is used as the master, and inputs when used as a slave (in cascade mode). These pins are outputs when in single mode. This dual function pin is used as an output to enable the data bus buffer in Buffered mode, and as an input for deciding whether the MSM82C59A-2 is to be master (SP/EN = 1) or slave (SP/EN =0) during Non-buffered mode. When an interrupt request is made to the MSM82C59A-2, the INT output is switched to high level, and INT interrupt is sent to the CPU. When this pin is at low level, the CALL instruction code or the interrupt vector data is enabled onto the data bus. When the CPU acknowledges the INT interrupt, INTA is sent to the MSM82C59A-2. (Interrupt acknowledge sequence). These interrupt request input pins for the MSM82C59A-2 can be set to edge trigger mode or level trigger mode ( by ICW1). In edge trigger mode, interrupt request is executed by the rising edge of the IR input and holds it until that input is acknowledged by the CPU. In level trigger mode, interrupt requests are executed by high level IR inputs and holds them until that input is acknowledged by the CPU. These pins have a pull up resistor. CS Chip Select Input Read Input Input RD Input WR A0 Write Input Address Input Input Input CAS0 - 2 Cascade Address Input/Output SP/EN Slave Program Input/Enable Input/Output Buffer Output Interrupt Output Interrupt Acknowledge Input INT Output INTA Input IR0 - 7 Request Input Input 8/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS SYSTEM INTERFACE Address Bus Control Bus Data Bus 8 bits CS A0 CAS0 CAS1 CAS2 D7 - D0 RD WR INT INTA Cascade Address Bus MSM82C59A-2 SP/EN IR0 IR1 IR2 IR3 IR4 IR5 IR6 IR7 Slave Program/Enable Buffer Interrupt Requests BASIC OPERATION DESCRIPTION Data transfers between the 82C59A-2 internal registers and the data bus are listed below. A0 0 1 0 0 0 1 ¥ ¥ ¥ D4 ¥ ¥ 0 0 1 ¥ ¥ ¥ ¥ D3 ¥ ¥ 0 1 ¥ ¥ ¥ ¥ ¥ RD 0 0 1 1 1 1 1 ¥ 0 WR 1 1 0 0 0 0 1 ¥ 0 CS 0 0 0 0 0 0 0 1 ¥ Function IRR, ISR, or Poll Word Æ Data Bus IMR Æ Data bus Data Bus Æ OCW2 Data Bus Æ OCW3 Data Bus Æ 1CW1 Data Bus Æ OCW1, ICW2, ICW3, ICW4 Data Bus Set to High Impedance (when INTA = 1) Combinations Prohibited Opearation Read Read Write Write Write Write — — 9/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS OPERATION DESCRIPTION The MSM82C59A-2 has been designed for real time interrupt driven microcomputer systems. The MSM82C59A-2 is capable of handling up to 8 levels of interrupt requests, and can be expanded to cover a maximum of 64 levels when connected to other MSM82C59A-2 devices. Programming involves the use of system software in the same way as other microcomputer peripheral I/O devices. Selection of priority mode involves program execution, and enables the method of requesting interrupts to be processed by the MSM82C59A-2 to be suitably configured for system requirements. That is, the priority mode can be dynamically updated or reconfigured during the main program at any time. A complete interrupt structure can be defined as required, based on the entire system environment. (1) Functional Description of Each Block Block Name IRR, ISR Description of Function IR input line interrupts are processed by a cascaded interrupt request register (IRR) and the in-service register (ISR). The IRR stores all request levels where interrupt service is requested, and the ISR stores all interrupt levels being serviced. This logic block determines the priority level of the bits set in the IRR. The highest priority level is selected, and the corresponding ISR bit is set during INTA pulses. This block is capable of receiving commands from the CPU. These command words (ICW) and the operation command words (OCW) store the various control formats for MSM82C59A-2 operations. This block is also used to transfer the status of the MSM82C59A-2 to the Data Bus. This functional block is involved in the output and comparison of all MSM82C59A-2 IDs used in the system. These three I/O pins (CAS0 thru CAS2) are outputs when the MSM82C59A-2 operates as a master, and inputs when it operates as a slave. When operating as a master, the MSM82C59A-2 sends a slave ID output to the slave where an interrupt has been applied. Furthermore, the selected slave sends the preprogrammed subroutine address onto the data bus during next one or two INTA pulses from the CPU. Priority Resolver Read/Write Logic Cascade Buffer Comparator (2) Interrupt Sequence The major features of the MSM82C59A-2 used in microcomputer systems are the programmability and the addressing capability of interrupt routines. This latter feature enables direct or indirect jumping to specific interrupt routines without polling the interrupt devices. The operational sequence during an interrupt varies for different CPUs. The procedure for the 85 system (MSM80C85AH) is outlined below. (i) One or more interrupt requests (IR0 thru IR7) becomes high, and the corresponding IRR bit is set. (ii) The MSM82C59A-2 evaluates these requests, and sends an INT signal to the CPU if the request is judged to be suitable. (iii) The CPU issues an INTA output pulse upon reception of the INT signal. (iv) Upon reception of the INTA signal from the CPU, the MSM82C59A-2 releases the CALL instruction code (11001101) to the 8-bit data bus. 10/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS (v) A further two INTA pulses are then sent to the MSM82C59A-2 from the CPU by this CALL instruction. (vi) These two INTA pulses result in a preprogrammed subroutine address being sent from the MSM82C59A-2 to the data bus. The lower 8-bit address is released by the first INTA pulse, and the higher 8-bit address is released by the second pulse. The Falling Edge of the second INTA signal sets the ISR bit with the highest priority, and the Rising Edge of it resets the IRR bit. (vii) 3-byte CALL instructions are thus released by the MSM82C59A-2. In Automatic End Of Interrupt (AEOI) mode, the IRS bit is reset at the end of the third INTA pulse. In other cases, the ISR bit remains set until reception of a suitable EOI command at the end of the interrupt routine. The procedure for the 86 system (MSM80C86A-10/88A-10) is identical to the first three steps of the 85 system. The subsequent steps are described below. (iv) Upon reception of the INTA signal from the CPU, the ISR bit with the highest priority is set, and the corresponding IRR bit is reset. In this cycle, the MSM82C59A-2 sets the data bus to high impedance without driving the Data Bus. (v) The CPU generates a second INTA output pulse, resulting in an 8-bit pointer to the data bus by the MSM82C59A-2. The Falling Edge of the INTA signal sets the ISR bit with the highest priority, and the Rising Edge of it resets the IRR bit. (vi) This completes the interrupt cycle. In AEOI mode, the ISR bit is reset at the end of the second INTA pulse. In other cases, the ISR bit remains set until reception of 3 suitable EOI command at the end of the interrupt routine. If the interrupt request is canceled prior to step (iv), that is, before the first INTA pulse has been received, the MSM82C59A-2 operates as if a level 7 interrupt has been received, and the vector byte and CAS line operate as if a level 7 interrupt has been requested. (3) Interrupt Sequence Output 85 Mode (MSM80C85AH) The sequence in this case consists of three INTA pulses. A CALL operation code is released to the data bus by the first INTA pulse. Contents of the First Interrupt Vector Byte CALL Code D7 1 D6 1 D5 0 D4 0 D3 1 D2 1 D1 0 D0 1 The lower address of the interrupt service routine is released to the data bus by the second INTApulse. If A5-A7 are programmed with an address interval of 4, A0-A4 are automatically inserted. And if A6 and A7 are programmed at an address interval of 8, A0-A5 are automatically inserted. Contents of the second interrupt vector byte 11/28 ¡ Semiconductor Contents of the Second Interrupt vector byte IR D7 7 6 5 4 3 2 1 0 IR D7 7 6 5 4 3 2 1 0 A7 A7 A7 A7 A7 A7 A7 A7 D6 A6 A6 A6 A6 A6 A6 A6 A6 D5 1 1 1 1 0 0 0 0 MSM82C59A-2RS/GS/JS Interval = 4 D6 A6 A6 A6 A6 A6 A6 A6 A6 D5 A5 A5 A5 A5 A5 A5 A5 A5 D4 1 1 1 1 0 0 0 0 D3 1 1 0 0 1 1 0 0 D2 1 0 1 0 1 0 1 0 D1 0 0 0 0 0 0 0 0 D0 0 0 0 0 0 0 0 0 A7 A7 A7 A7 A7 A7 A7 A7 Interval = 8 D4 1 1 0 0 1 1 0 0 D3 1 0 1 0 1 0 1 0 D2 0 0 0 0 0 0 0 0 D1 0 0 0 0 0 0 0 0 D0 0 0 0 0 0 0 0 0 The higher address of the interrupt service routine programmed by the second bytes (A8 A15) of the initialization sequence is released to the data bus. Contents of the Third Interrupt Vector Byte D7 A15 D6 A14 D5 A13 D4 A12 D3 A11 D2 A10 D1 A9 D0 A8 86 Mode (MSM80C86A-10/88A-10) Apart from the two interrupt acknowledge cycles and the absence of a CALL operation code, the 86 mode is the same as the 85 mode. The first INTA cycle freezes interrupt status to resolve the priority internally in the same way as in 85 mode. When the device is used as a master, an interrupt code is issued to the cascade line at the end of the INTA pulse. During this first cycle, the data bus buffer is kept at high impedance without any data to the CPU. During the second INTA cycle, the MSM82C59A-2 sends a byte of interrupt code to the CPU. Note that in 86 mode, the Address Interval (ADI) control status is ignored and A5-A10 is not used. 12/28 ¡ Semiconductor Contents of Interrupt Vector Byte in 86 System Mode D7 IR7 IR6 IR5 IR4 IR3 IR2 IR1 IR0 T7 T7 T7 T7 T7 T7 T7 T7 D6 T6 T6 T6 T6 T6 T6 T6 T6 D5 T5 T5 T5 T5 T5 T5 T5 T5 D4 T4 T4 T4 T4 T4 T4 T4 T4 D3 T3 T3 T3 T3 T3 T3 T3 T3 MSM82C59A-2RS/GS/JS D2 1 1 1 1 0 0 0 0 D1 1 1 0 0 1 1 0 0 D0 1 0 1 0 1 0 1 0 (4) Programming the MSM82C59A-2 The MSM82C59A-2 receives two types of command words generated by the CPU. (i) Initialization Command Words (ICW1 thru ICW4) Before commencing normal operations, each MSM82C59A-2 in the system must be initialized by two to four WR pulse sequence. ICW1 ICW2 In Cascade Mode? Yes (SNGL = 0) ICW3 No (SNGL = 1) No (IC4 = 0) Is ICW4 needed? Yes (IC4 = 1) ICW4 Interrupt request reception preparations completed Initialization Sequence 13/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS (ii) Operation Command Words (OCW1 thru OCW3) These commands are used in operating the MSM82C59A-2 in the following modes. a. Fully Nested Mode b. Rotating Priority Mode c. Special Mask Mode d. Polled Mode The OCW can be written into the MSM82C59A-2 any time after initialization has been completed. (5) Initialization Command Words (ICW1 thru ICW4) When a command is issued with D4 = 1 and A0 = 0, it is always regarded as an Initialization Command Word 1 (ICW1). Starting of the initialization sequence by ICW1 results in automatic execution of the following steps. a. The edge sense circuit is reset, and a low to high transition is necessary to generate an interrupt. b. The interrupt mask register is cleared. c. The IR7 input is assigned priority 7 (lowest priority) d. Slave mode address is set to 7. e. The Special Mask Mode is cleared, and the Status Read is set to IRR. f. All ICW4 functions are cleared if IC4 = 0, resulting in a change to Non-Buffered mode, noAuto EOI, and 85 mode. Note: Master/slave in ICW4 can only be used in buffered mode. (i) Initialization Command Words 1 and 2 (ICW1 and ICW2) A4 thru A15: (Starting address of interrupt service routines) In 85 mode, 8 request levels CALL 8 locations at equivalent intervals in the memory. The memory location interval can be set at this stage to 4 or 8 by program. (ÆADI)Hence, either 32 or 64 bytes/page respectively are used in the 8 routines. The address format is 2 bytes long (A0 thru A15). When the routine interval is 4, A0 thru A4 are inserted automatically by the MSM82C59A2, and A5 thru A15 are programmed externally. When the interval is 8, on the other hand, A0 thru A5 are inserted automatically by the MSM82C59A-2, and A6 thru A15 are programmed externally. In 86 mode, T3 thru T7 are inserted in the 5 most significant bits of the vector type. And the MSM82C59A-2 sets the 3 least significant bits according to the interrupt level. A0 thru A10 are ignored, and the ADI (address interval) has no effect. LTIM: The MSM82C59A-2 is operated in level triggered mode when LTIM = 1, and the interrupt input edge circuit becomes disabled. ADI: Designation of the CALL address interval. Interval = 4 when ADI = 1, and interval = 8 when ADI = 0. SNGL: SNGL = 1 indicates the existence of only one MSM82C59A-2 in the system. ICW3 is not required when SNGL = 1. IC4: ICW4 is required when this bit is set, but not required when IC4 = 0. 14/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS (ii) Initialization Command Word 3 (ICW3) This command word is written when there is more than one MSM82C59A-2 used in cascade connections in the system, and is loaded into an 8-bit slave register. The functions of this slave register are listed below. a. In a master mode system (BUF = 1 and M/ S = 1 in ICW4 or SP/EN = 1). “1” is set in each bit where a slave has been connected. In 85 mode, the master MSM82C59A-2 releases byte 1 of the CALL sequence to enable the corresponding slave to release byte 2 or 3 (only byte 2 in 86 mode) through the cascade line. b. In slave mode (BUF = 1 and M/S = 0 in ICW4 or SP/EN = 0). Bits 0 thru 2 identify the slave. The slave compares these bits with the cascade input, and releases bytes 2 and 3 of the CALL sequence (only byte 2 in 86 mode) if a matching result is obtained. (iii) Initialization Command Word 4 (ICW4) SFNM: Special Fully Nested Mode is programmed when SFNM = 1. BUF: Buffered mode is programmed when BUF = 1. In Buffered mode, SP/EN is an output, and Master/slave is selected by the M/S bit. M/S: If buffered mode is selected, the MSM82C59A-2 is programmed as the master when M/S = 1, and as a slave when M/S = 0. M/S is ignored, however, when BUF = 0. AEOI: Automatic End Of Interrupt mode is programmed by AEOI = 1. mPM: (Microprocessor mode) The MSM82C59A-2 is set to 85 system operation when mPM = 0, and to 86 system operation when mPM = 1. 15/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS A0 ICW1 0 D7 A7 D6 A6 D5 A5 D4 1 D3 LTIM D2 ADI D1 SNGL D0 IC4 1: ICW4 required 0: ICW4 not required 1: Single 0: Cascade CALL address interval 1: Interval = 4 0: Interval = 8 1: Level triggered mode 0: Edge triggered mode Interrupt vector address A5 thru A7 (Valid only in 85 mode) A0 ICW2 1 D7 A15/T7 D6 A14/T6 D5 A13/T5 D4 A12/T4 D3 A11/T3 D2 A10 D1 A9 D0 A8 Interrupt vector address A8 thru A15 (85 mode) Interrupt vector address T3 thru T7 (86 mode) A0 ICW3 (Master) 1 D7 S7 D6 S6 D5 S5 D4 S4 D3 S3 D2 S2 D1 S1 D0 S0 1: IR input holds slave 0: IR input does not hold slave A0 ICW3 (Slave) 1 D7 0 D6 0 D5 0 D4 0 D3 0 D2 ID2 D1 ID1 D0 ID0 Slave ID 0 0 0 0 1 1 0 0 2 0 1 0 3 1 1 0 4 0 0 1 5 1 0 1 6 0 1 1 7 1 1 1 NOTE: Slave ID indicates the IR input of the corresponding master. A0 ICW4 1 D7 0 D6 0 D5 0 D4 SFNM D3 BUF D2 M/S D1 AEOI D0 mPM 1: 86 mode 0: 85 mode 1: Automatic EOI mode 0: Normal EOI mode 0 1 1 ¥ 0 1 Non-buffered mode Buffered mode (slave) Buffered mode (master) NOTE: ¥ den 0 tes not specified 1: Special fully nested mode 0: Not special fully nested mode Initialization Command Words (ICW1 thru ICW4) 16/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS (6) Operation Command Words (OCW1 thru OCW3) When Initialization Command Words (ICWs) are programmed in the MSM82C59A-2, the interrupt input line is ready to receive interrupt requests. The Operation Command Words (OCWs) enable the MSM82C59A-2 to be operated in various modes while the device is in operation. (i) Operation Command Word 1 (OCW1) OCW1 sets and resets the mask bits of the Interrupt Mask Register (IMR). M0 thru M7 represent 8 mask bits. The channel is masked when M = 1, but is enabled when M = 0. (ii) Operation Command Word 2 (OCW2) R, SL, EOI: The Priority Rotation and End of Interrupt mode plus combinations of the two are controlled by combinations of these 3 bits. These combinations are listed in the operation command word format table. L2, L1, L0: These bits indicate the specified interrupt level when SL = 1. (iii) Operation Command Word 3 (OCW3) ESMM: This enables the Special Mask Mode. The special mask mode can be set and reset by the SMM bit when ESMM = 1. The SMM bit is ignored when ESMM = 0. SMM: (Special Mask Mode) The MSM82C59A-2 is set to Special Mask Mode when ESMM = 1 and SMM = 1, and is returned to normal mask mode when ESMM = 1 and SMM = 0. SMM is ignored when ESMM = 0. 17/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS A0 OCW1 1 D7 M7 D6 M6 D5 M5 D4 M4 D3 M3 D2 M2 D1 M1 D0 M0 Intterupt Mask 1: Mask set 0: Mask reset A0 OCW2 0 D7 R D6 SL D5 EOI D4 0 D3 0 D2 L2 D1 L1 D0 L0 Active IR Level 0 0 0 0 1 1 0 0 2 0 1 0 3 1 1 0 4 0 0 1 5 1 0 1 6 0 1 1 7 1 1 1 0 0 1 1 0 1 1 0 0 1 0 0 0 1 1 1 1 1 1 0 0 1 0 0 Non-specific EOI command Specific EOI command (NOTE) Rotate on non-specific EOI command Rotate in automatic EOI mode (SET) Rotate in automatic EOI mode (Clear) Rotate on specific EOI command (NOTE) Set priority comand (NOTE) No operation End of interrupt Automatic rotation Specific rotation NOTE: L0 thru L2 used A0 OCW3 0 D7 0 D6 ESMM D5 SMM D4 0 D3 1 D2 P D1 RR D0 RIS Read Register Command 0 0 1 0 0 1 Read IRR by next RD 1 1 Read ISR by next RD No operation Polling 1: Poll command 0: No-poll command Special Mask Mode 0 0 1 0 0 1 Reset special mask mode 1 1 Set special mask mode No operation Operation Command Words (OCW1 thru OCW3) 18/28 ¡ Semiconductor (7) Fully Nested Mode MSM82C59A-2RS/GS/JS As long as the MSM82C59A-2 has not been programmed to another mode, this Fully Nested mode is set automatically after initialization. The interrupt requests are ordered in priority sequentially from 0 to 7 (where 0 represents highest priority). If an interrupt is then requested and is acknowledged highest priority, a corresponding vector address is released, and the corresponding bit in the in-service register (ISR) is set. The IS bit remains set until an End of Interrupt (EOI) command is issued from the microprocessor before returning from the interrupt service routine, or until the rising edge of the last INTA pulse arrives when the AEOI bit has been set. When the IS bit is set, interrupts of the same or lower priority are inhibited - only interrupts of higher priority can be generated. In this case, interrupts can be acknowledged only when the internal interrupt enable F/F in the microprocessor has been enabled again through software. Following the initialization sequence, IR0 has the highest priority, and IR7 has the lowest. This priority can be changed by rotating priority mode in OCW2. (8) End of Interrupt (EOI) When the AEOI bit in ICW4 is set, the in-service (IS) bit is automatically reset by the rising edge of the last INTA pulse, or else is reset only when an EOI command is issued to the MSM82C59A-2 prior to returning from the interrupt service routine. And in cascade mode, the EOI command must be issued twice - once for the master, and once for the corresponding slave. EOI commands are classified into specific EOI commands and Non-Specific EOI commands. When the MSM82C59A-2 is operated in Fully Nested mode, the IS bit to be reset can be determined on EOI. If the Non-Specific EOI command is issued, the highest IS bit of those that are set is reset automatically, because the highest IS level is always the last servicing level in the Fully Nested mode, the MSM82C59A-2 will no longer be able to determine the last acknowledged level. In this case, it will be necessary to issue a Specific EOI which includes the IS level to be reset as part of the command. When the MSM82C59A-2 is in Special Mask mode, care must be taken to ensure that IS bits masked by the IMR bit can not reset by the Non-Specific EOI. (9) Automatic End of Interrupt (AEOI) Mode When AEOI = 1 in ICW4, the MSM82C59A-2 continues to operate in AEOI mode until programmed again by ICW4. In this mode, the MSM82C59A-2 automatically performs Non-Specific EOI operation at the rising edge of the last INTA pulse (the third pulse in 85 systems, and the second pulse in 86 systems). In terms of systems, this mode is best used in nested multiple level interrupt configurations. It is not necessary when there is only one MSM82C59A-2. AEOI mode is only used in a master MSM82C59A-2 device, not in a slave. (10) Automatic Rotation (Devices with Equal Priority) In some applications, there is often a number of devices with equal priority. In this mode, the device where an interrupt service has just been completed is set to the lowest priority. At worst, therefore, a particular interrupt request device may have to wait for seven other devices to be serviced at least once each. There are two methods for Automatic Rotation using OCW2 - Rotation on Non-Specific EOI command, and Rotation in Automatic EOI mode. 19/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS Before Rotation (IR4 the highest priority requesting service) IS7 IS6 IS5 IS4 IS3 IS2 IS1 IS0 IS Status Priority Status 0 7 Lowest 1 6 0 5 1 4 0 3 0 2 0 1 0 0 Highest After Rotation (IR4 was serviced, all other priorities rotated correspondingly) IS7 IS6 IS5 IS4 IS3 IS2 IS1 IS0 IS Status Priority Status 0 2 1 1 0 0 Highest Lowest 0 7 0 6 0 5 0 4 0 3 (11) Specific Rotation (Specific Priority) All priority levels can be changed by programming the lowest priority level (Set Priority Command in OCW2). For example, if IR5 is programmed as the device of lowest priority, IR6 will have the highest priority. In this mode, the internal status can be updated during OCW2 by software control. This is unrelated, however, to the EOI command in the same OCW2. Priority level can also be changed by using the OCW2 Rotate On Specific EOI command. (12) Interrupt Mask Interrupt inputs can be masked individually by Interrupt Mask Registers (IMR) programmed through the OCW1. Each interrupt channel is masked (disabled) when the respective IMR bit is set to “1”. IR0 is masked by bit 0, and IR1 is masked by bit 1. Masking of any particular channel has no effect on other channels. 20/28 ¡ Semiconductor (13) Special Mask Mode MSM82C59A-2RS/GS/JS In some applications, there is a need for dynamic updating of the system’s priority level structure by software control during execution of an interrupt service routine. For example, it may be necessary to inhibit the lower priority requests for part of the execution of a certain routine while enabling for another part. In this case, it is difficult to enable all lower priority requests if the IS bit has not yet been reset by the EOI command after an interrupt request has been acknowledge (during execution of a service routine). All of these requests would normally be disabled. Hence the use of the Special Mask mode. When a mask bit is set by OCW1 in this mode, the corresponding interrupt level requests are disabled. And all other unmasked level requests (at both higher and lower priority levels) are enabled. Interrupts can thus be enabled selectively by loading the mask register. In this mode, the specific EOI Command should be used. This Special Mask mode is set by OCW3 ESMM = 1 and SMM = 1, and reset by ESMM = 1 and SMM = 0. (14) POLL Command In this mode, the INT output is not used, the internal interrupt enable F/F of the microprocessor is reset, and interrupt inputs are disabled. Servicing the I/O device is executed by software using the Poll command. The Poll command is issued by setting P in OCW3 to “1”. The MSM82C59A-2 regards the next RD pulse as reception of an interrupt, and if there is a request, the corresponding IS bit is set and the priority level is read out. Interrupts are frozen between WR and RD. D7 Poll Word 1 D6 0 D5 0 D4 0 D3 0 D2 D1 D0 W2 W1 W0 W0 thru W2: Binary coded highest priority level of service being requested. 1: Set to "1" when there is an interrupt. This mode is useful when there is a command routine for a number of levels, and the INTA sequence is not required. ROM space can thus be saved. 21/28 ¡ Semiconductor (15) Reading MSM82C59A-2 Status MSM82C59A-2RS/GS/JS The status of a number of internal registers can be read out for updating user information on the system. The following registers can be read by means of OCW3 (IRR and ISR) and OCW1 (IMR). a. IRR: (Interrupt Request Register) 8-bit register for storing interrupt requesting levels. b. ISR: (In-Service Register) 8-bit register for storing priority levels being serviced. c. IMR: (Interrupt Mask Register) 8-bit register for storing interrupt request lines to be masked. The IRR can be read when a Read Register Command is issued with OCW3 (RR = 1 and RIS = 0) prior to the RD pulse, and the ISR can be read when a Read Register command is issued with OCW3 (RR = 1 and RIS = 1) prior to the RD pulse. And as long as the read status does not change, OCW3 is not required each time before the status is read. This is because the MSM82C59A-2 remembers whether IRR or ISR was selected by the previous OCW3. But this is not true when poll is used. The MSM82C59A-2 is set to IRR after initialization. OCW3 is not required to read IMR. IMR is issued to the data bus if RD = 0 and A0 = 1 (OCW1). Reading status is disabled by polling when P = 1 and RR = 1 in OCW3. (16) Edge and Level Trigger Mode This mode is programmed by using bit 3 (LTIM) in ICW1. When LTIM = 0, the interrupt request is recognized by the IR input transition from Low to High. As long as the IR input is kept at High, no other interrupt is generated. Since interrupt requests are recognized by the IR input “H” level when LTIM = 1, edge detection is not required. The interrupt request must be cancelled before output of the EOI command, and before the interrupt is enabled in order to prevent the generation of a second interrupt by the CPU. The IR input must be held at High level until the falling edge of the first INTA pulse, irrespective of whether edge sense or level sense is employed. If the IR input is switched to Low level before the first INTA pulse, the default IR7 is generated when the interrupt is acknowledged by the CPU. This can be an effective safeguard to be adopted to detect interrupts generated by the noise glitches on the IR inputs. To take advantage of this feature, the IR7 routine is used as a “clean up” routine where the routine is simply executing a return instruction and the interrupt is subsequently ignored. When the IR7 is required for other purposes, the default IR7 can be detected by reading the ISR. Although correct IR7 interrupts involve setting of the corresponding ISR bit, the default IR7 is not set. IR7 routine No (IR noise detection) IS7=1? Yes IR7 service processing EOI RETURN 22/28 ¡ Semiconductor (17) Special Fully Nested Mode MSM82C59A-2RS/GS/JS This mode is used in large systems where the cascade mode is used and the respective Interrupt Requests within each slave have to be given priority levels. In this case, the Special Fully Nested mode is programmed to the master by using ICW4. This mode is practically identical to the normal Fully Nested mode, but differs in the following two respects. a. When an interrupt request is received from a particular slave during servicing, a new interrupt request from an IR with a higher priority level than the interrupt level of the slave being serviced is recognized by the master and the interrupt is applied to the processor without the master priority logic being inhibited by the slave. In normal Fully Nested mode, if the request is in service, a slave is masked and no other requests can be recognized from the same slave. b. When exiting from an interrupt service routine, it is first necessary to check whether or not the interrupt which has just been serviced by soft ware was the only interrupt from that slave. This is done by sending a Non-Specific EOI command to that slave, followed by reading of the In-Service Register (ISR) to see whether that register has become all ‘0’. A Non-Specific EOI is sent to the master too if the ISR is empty, and if not no EOI should be sent. (18) Buffered Mode Control for buffer enabling is required when the MSM82C59A-2 is used in a large system where a data bus drive buffer is needed and cascade mode is used. When buffered mode is selected, the MSM82C59A-2 sends an enable signal on the SP/EN pin to enable the buffer. In this mode, the SP/EN output always becomes active while the MSM82C59A2’s data bus output is enabled. Therefore, the MSM82C59A-2 requires programming to enable it to distinguish master from slave. Buffered mode is programmed by bit 3 in ICW4, and the ability to distinguish master from slave is programmed by bit 2 in ICW4. (19) Cascade Mode To enable the MSM82C59A-2 to handle up to 64 priority levels, a maximum of 8 slaves can be easily connected to one master device. The master controls the slaves through three cascade lines, the cascade bus executes like a slave chip select during the INTA sequence. In cascade configuration, slave interrupt outputs (INT) are connected to master interrupt request inputs (IR). When a slave IR becomes active and is acknowledged, the master enables the corresponding slave to release the routine address for that device during bytes 2 and 3 (only byte 2 in 86 mode) of the INTA sequence. The cascade bus line is normally kept at low level, and holds the slave address during the period from the rising edge of the first INTA pulse up to the rising edge of the thirdINTA pulse (or the second INTA pulse in 86 mode). Each MSM82C59A-2 device in the system can operate in different modes in accordance with their initialization sequences. EOI commands must be issued twice, once for the master once for the corresponding slave. Each MSM82C59A-2 requires an address decoder to activate the respective chip select (CS) inputs. Since the cascade line is normally kept at low level, note that slaves must be connected to the master IR0 only after all slaves have been connected to the other IRs. 23/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS Address Bus Control Bus Data Bus Cascade Bus CS A0 D0 - 7 INTA MSM82C59A-2 CAS0 - 2 INT SP/EN (Slave) 76543210 GND CS A0 D0 - 7 INTA MSM82C59A-2 CAS0 - 2 INT SP/EN (Slave) 76543210 GND CS A0 D0 - 7 INTA CAS0 - 2 MSM82C59A-2 INT (Master) SP/EN M7 M6 M5 M4 M3 M2 M1 M0 VCC 76543210 76543210 7 54 210 Interrupt Requests MSM82C59A-2 Cascade Connections 24/28 ¡ Semiconductor Precautions for operation MSM82C59A-2RS/GS/JS Contents: In the case of a cascade edge trigger, the low level width (TILIH) of a slave INT signal may be less than the low level width (TJLJH:100 ns min.) of a master IR input signal. This occurs when an interruption request with high order priority is provided to the slave unit before the INTA cycle ends. Fig.1 shows a system configuration, Fig.2 a bug operation timing chart, and Fig.3 a normal operation timing chart. TILIH is not specified. CPU MSM82C59A-2 Master MSM82C59A-2 Slave IR1 INTR INTA INTm INT INTA IR7 INTs IR2 INT INTA IR1s IR2s IR7m Fig. 1 System Configuration IR2S IR1S INTA INTS (IR7m) INTm TILIH (TJLJH) does not satisfy the spec. INTS is not accepted. Fig. 2 Bug Operation Timing Chart IR2S IR1S INTA INTS (IR7m) TILIH (TJLJH) INTm Fig. 3 Normal Operation Timing Chart 25/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS PACKAGE DIMENSIONS (Unit : mm) DIP28-P-600-2.54 Package material Lead frame material Pin treatment Solder plate thickness Package weight (g) Epoxy resin 42 alloy Solder plating 5 mm or more 4.30 TYP. Notes for Mounting the Surface Mount Type Package The SOP, QFP, TSOP, SOJ, QFJ (PLCC), SHP and BGA are surface mount type packages, which are very susceptible to heat in reflow mounting and humidity absorbed in storage. Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the product name, package name, pin number, package code and desired mounting conditions (reflow method, temperature and times). 26/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS (Unit : mm) QFJ28-P-S450-1.27 Spherical surface Package material Lead frame material Pin treatment Solder plate thickness Package weight (g) Epoxy resin Cu alloy Solder plating 5 mm or more 1.00 TYP. Notes for Mounting the Surface Mount Type Package The SOP, QFP, TSOP, SOJ, QFJ (PLCC), SHP and BGA are surface mount type packages, which are very susceptible to heat in reflow mounting and humidity absorbed in storage. Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the product name, package name, pin number, package code and desired mounting conditions (reflow method, temperature and times). 27/28 ¡ Semiconductor MSM82C59A-2RS/GS/JS (Unit : mm) SSOP32-P-430-1.00-K Mirror finish Package material Lead frame material Pin treatment Solder plate thickness Package weight (g) Epoxy resin 42 alloy Solder plating 5 mm or more 0.60 TYP. Notes for Mounting the Surface Mount Type Package The SOP, QFP, TSOP, SOJ, QFJ (PLCC), SHP and BGA are surface mount type packages, which are very susceptible to heat in reflow mounting and humidity absorbed in storage. Therefore, before you perform reflow mounting, contact Oki’s responsible sales person for the product name, package name, pin number, package code and desired mounting conditions (reflow method, temperature and times). 28/28
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