INTERSIL ID82C89

82C89
CMOS Bus Arbiter
March 1997
Features
Description
• Pin Compatible with Bipolar 8289
The Intersil 82C89 Bus Arbiter is manufactured using a selfaligned silicon gate CMOS process (Scaled SAJI IV). This circuit, along with the 82C88 bus controller, provides full bus arbitration and control for multi-processor systems. The 82C89 is
typically used in medium to large 80C86 or 80C88 systems
where access to the bus by several processors must be coordinated. The 82C89 also provides high output current and capacitive drive to eliminate the need for additional bus buffering.
• Performance Compatible with:
- 80C86/80C88 . . . . . . . . . . . . . . . . . . . . . . . . . .(5/8MHz)
• Provides Multi-Master System Bus Control and
Arbitration
• Provides Simple Interface with 82C88/8288 Bus
Controller
Static CMOS circuit design insures low operating power. The
advanced Intersil SAJI CMOS process results in performance equal to or greater than existing equivalent products
at a significant power savings.
• Synchronizes 80C86/8086, 80C88/8088 Processors
with Multi-Master Bus
• Bipolar Drive Capability
• Four Operating Modes for Flexible System Configuration
• Low Power Operation
- ICCSB . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10µA (Max)
- ICCOP . . . . . . . . . . . . . . . . . . . . . . . . .1mA/MHz (Max)
• Operating Temperature Ranges
- C82C89 . . . . . . . . . . . . . . . . . . . . . . . . . .0oC to +70oC
- I82C89 . . . . . . . . . . . . . . . . . . . . . . . . . -40oC to +85oC
- M82C89 . . . . . . . . . . . . . . . . . . . . . . . -55oC to +125oC
Ordering Information
PART NUMBER
TEMPERATURE
RANGE
PACKAGE
PKG.
NO.
0oC to +70oC
E20.3
IP82C89
-40oC to +85oC
E20.3
CS82C89
20 Ld PLCC
0oC to +70oC
-40oC to +85oC
N20.35
20 Ld
CERDIP
0oC to +70oC
-40oC to +85oC
F20.3
-55oC to +125oC
F20.3
-55oC to +125oC
J20.A
CP82C89
20 Ld PDIP
IS82C89
CD82C89
ID82C89
MD82C89/B
5962-8552801RA
MR82C89/B
SMD#
F20.3
F20.3
20 Pad
CLCC
5962-85528012A
N20.35
SMD#
J20.A
Pinouts
18 S0
RESB
4
17 CLK
BCLK
5
16 LOCK
INIT
6
15 CRQLCK
BREQ
7
14 ANYRQST
BPRO
8
13 AEN
BPRN
9
12 CBRQ
GND 10
11 BUSY
3
2
1
20
19
RESB
4
18 S0
BCLK
5
17 CLK
INIT
6
16 LOCK
BREQ
7
15 CRQLCK
BPRO
8
14 ANYRQST
CAUTION: These devices are sensitive to electrostatic discharge; follow proper IC Handling Procedures.
http://www.intersil.com or 407-727-9207 | Copyright © Intersil Corporation 1999
4-343
S1
3
9
10
11
12
13
AEN
SYSB/RESB
VCC
19 S1
CBRQ
2
S2
IOB
BUSY
20 VCC
GND
1
BPRN
S2
IOB
82C89 (PLCC, CLCC)
TOP VIEW
SYSB/
RESB
82C89 (CERDIP)
TOP VIEW
File Number
2980.1
82C89
Functional Diagram
STATUS
INIT
BCLK
BREQ
BPRN
BPRO
DECODER
BUSY
ARBITRATION
S2
S1
S0
80C86/
80C88
STATUS
LOCK
CLK
CRQLCK
RESB
ANYRQST
CONTROL/
STRAPPING
OPTIONS
MULTIBUS
INTERFACE
MULTIBUSTM
COMMAND
SIGNALS
CBRQ
CONTROL
LOCAL
BUS
INTERFACE
IOB
AEN
SYSB/
RESB
+5V
SYSTEM
SIGNALS
GND
MULTIBUSTM IS AN INTEL CORP. TRADEMARK
Pin Description
PIN
SYMBOL
NUMBER
VCC
20
VCC: The +5V Power supply pin. A 0.1µF capacitor between pins 10 and 20 is recommended for
decoupling.
GND
10
GROUND.
S0, S1, S2
1, 18-19
I
STATUS INPUT PINS: The status input pins from an 80C86, 80C88 or 8089 processor. The
82C89 decodes these pins to initiate bus request and surrender actions. (See Table 1).
CLK
17
I
CLOCK: From the 82C84A or 82C85 clock chip and serves to establish when bus arbiter actions
are initiated.
LOCK
16
I
LOCK: A processor generated signal which when activated (low) prevents the arbiter from surrendering the multi-master system bus to any other bus arbiter, regardless of its priority.
CRQLCK
15
I
COMMON REQUEST LOCK: An active low signal which prevents the arbiter from surrendering the
multi-master system bus to any other bus arbiter requesting the bus through the CBRQ input pin.
RESB
4
I
RESIDENT BUS: A strapping option to configure the arbiter to operate in systems having both a
multi-master system bus and a Resident Bus. Strapped high, the multi-master system bus is requested or surrendered as a function of the SYSB/RESB input pin. Strapped low, the SYSB/RESB
input is ignored.
ANYRQST
14
I
ANY REQUEST: A strapping option which permits the multi-master system bus to be surrendered
to a lower priority arbiter as if it were an arbiter of higher priority (i.e., when a lower priority arbiter
requests the use of the multi-master system bus, the bus is surrendered as soon as it is possible).
When ANYRQST is strapped low, the bus is surrendered according to Table A in Design Information. If ANYRQST is strapped high and CBRQ is activated, the bus is surrendered at the end of
the present bus cycle. Strapping CBRQ low and ANYRQST high forces the 82C89 arbiter to surrender the multi-master system bus after each transfer cycle. Note that when surrender occurs
BREQ is driven false (high).
TYPE
DESCRIPTION
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82C89
Pin Description
(Continued)
PIN
SYMBOL
NUMBER
TYPE
DESCRIPTION
IOB
2
I
IO BUS: A strapping option which configures the 82C89 Arbiter to operate in systems having both
an IO Bus (Peripheral Bus) and a multi-master system bus. The arbiter requests and surrenders
the use of the multi-master system bus as a function of the status line, S2. The multi-master system bus is permitted to be surrendered while the processor is performing IO commands and is
requested whenever the processor performs a memory command. Interrupt cycles are assumed
as coming from the peripheral bus and are treated as an IO command.
AEN
13
O
ADDRESS ENABLE: The output of the 82C89 Arbiter to the processor’s address latches, to the
82C88 Bus Controller and 82C84A or 82C85 Clock Generator. AEN serves to instruct the Bus
Controller and address latches when to three-state their output drivers.
INIT
6
I
INITIALIZE: An active low multi-master system bus input signal used to reset all the bus arbiters
on the multi-master system bus. After initialization, no arbiters have the use of the multi-master
system bus.
SYSB/RESB
3
I
SYSTEM BUS/RESIDENT BUS: An input signal when the arbiter is configured in the System/Resident Mode (RESB is strapped high) which determines when the multi-master system bus is requested and multi-master system bus surrendering is permitted. The signal is intended to originate
from a form of address-mapping circuitry, such as a decoder or PROM attached to the resident
address bus. Signal transitions and glitches are permitted on this pin from θ1 of T4 to θ1 of T2 of
the processor cycle. During the period from θ1 of T2 to θ1 of T4, only clean transitions are permitted on this pin (no glitches). If a glitch occurs, the arbiter may capture or miss it, and the multi-master system bus may be requested or surrendered, depending upon the state of the glitch. The
arbiter requests the multi-master system bus in the System/Resident Mode when the state of the
SYSB/RESB pin is high and permits the bus to be surrendered when this pin is low.
CBRQ
12
I/O
COMMON BUS REQUEST: An input signal which instructs the arbiter if there are any other arbiters of lower priority requesting the use of the multi-master system bus.
The CBRQ pins (open-drain output) of all the 82C89 Bus Arbiters which surrender to the multimaster system bus upon request are connected together.
The Bus Arbiter running the current transfer cycle will not itself pull the CBRQ line low. Any other
arbiter connected to the CDRQ line can request the multi-master system bus. The arbiter presently
running the current transfer cycle drops its BREQ signal and surrenders the bus whenever the
proper surrender conditions exist. Strapping CBRQ low and ANYRQST high allows the multi-master system bus to be surrendered after each transfer cycle. See the pin definition of ANYRQST.
BCLK
5
I
BUS CLOCK: The multi-master system bus clock to which all multi-master system bus interface
signals are synchronized.
BREQ
7
O
BUS REQUEST: An active low output signal in the Parallel Priority Resolving Scheme which the
arbiter activates to request the use of the multi-master system bus.
BPRN
9
I
BUS PRIORITY IN: The active low signal returned to the arbiter to instruct it that it may acquire the
multi-master system bus on the next falling edge of BCLK. BPRN active indicates to the arbiter that
it is the highest priority requesting arbiter presently on the bus. The loss of BPRN instructs the arbiter that it has lost priority to a higher priority arbiter.
BPRO
8
O
BUS PRIORITY OUT: An active low output signal used in the serial priority resolving scheme
where BPRO is daisy-chained to BPRN of the next lower priority arbiter.
BUSY
11
I/O
BUSY: An active low open-drain multi-master system bus interface signal used to instruct all the
arbiters on the bus when the multi-master system bus is available. When the multi-master system
bus is available the highest requesting arbiter (determined by BPRN) seizes the bus and pulls
BUSY low to keep other arbiters off of the bus. When the arbiter is done with the bus, it releases
the BUSY signal, permitting it to go high and thereby allowing another arbiter to acquire the multimaster system bus.
4-345
82C89
Functional Description
decoded by a decoder to select the corresponding BPRN
(Bus Priority In) line to be returned to the highest priority
requesting arbiter. The arbiter receiving priority (BPRN true)
then allows its associated bus master onto the multi-master
system bus as soon as it becomes available (i.e., the bus is
no longer busy). When one bus arbiter gains priority over
another arbiter it cannot immediately seize the bus, it must
wait until the present bus transaction is complete. Upon
completing its transaction the present bus occupant recognizes that it no longer has priority and surrenders the bus by
releasing BUSY. BUSY is an active low “OR” tied signal line
which goes to every bus arbiter on the system bus. When
BUSY goes inactive (high), the arbiter which presently has
bus priority (BPRN true) then seizes the bus and pulls BUSY
low to keep other arbiters off of the bus. See waveform timing diagram, Figure 2. Note that all multimaster system bus
transactions are synchronized to the bus clock (BCLK). This
allows the parallel priority resolving circuitry or any other priority resolving scheme employed to settle.
BUS
ARBITER
1
BREQ
BPRN
BREQ
BUS
ARBITER BPRN
2
BREQ
BUS
ARBITER
3
In general, higher priority masters obtain the bus when a
lower priority master completes its present transfer cycle.
Lower priority bus masters obtain the bus when a higher priority master is not accessing the system bus. A strapping
option (ANYRQST) is provided to allow the arbiter to surrender the bus to a lower priority master as though it were a
master of higher priority. If there are no other bus masters
requesting the bus, the arbiter maintains the bus so long as
its processor has not entered the HALT State. The arbiter will
not voluntarily surrender the system bus and has to be forced
off by another master’s bus request, the HALT State being
the only exception. Additional strapping options permit other
modes of operation wherein the multi-master system bus is
surrendered or requested under different sets of conditions.
74HC148
PRIORITY
ENCODER
••
••
Arbitration Between Bus Masters
74HC138
3 TO 8
ENCODER
••
••
The 82C89 Bus Arbiter operates in conjunction with the
82C88 Bus Controller to interface 80C86, 80C88 processors
to a multi-master system bus (both the 80C86 and 80C88
are configured in their max mode). The processor is
unaware of the arbiter’s existence and issues commands as
though it has exclusive use of the system bus. If the processor does not have the use of the multi-master system bus,
the arbiter prevents the Bus Controller (82C88), the data
transceivers and the address latches from accessing the
system bus (e.g. all bus driver outputs are forced into the
high impedance state). Since the command sequence was
not issued by the 82C88, the system bus will appear as “Not
Ready” and the processor will enter wait states. The processor will remain in Wait until the Bus Arbiter acquires the use
of the multi-master system bus whereupon the arbiter will
allow the bus controller, the data transceivers, and the
address latches to access the system. Typically, once the
command has been issued and a data transfer has taken
place, a transfer acknowledge (XACK) is returned to the processor to indicate “READY” from the accessed slave device.
The processor then completes its transfer cycle. Thus the
arbiter serves to multiplex a processor (or bus master) onto
a multi-master system bus and avoid contention problems
between bus masters.
BPRN
BREQ
BUS
ARBITER BPRN
4
•
•
BUSY
CBRQ
•
•
FIGURE 1. PARALLEL PRIORITY RESOLVING TECHNIQUE
Priority Resolving Techniques
Since there can be many bus masters on a multi-master system bus, some means of resolving priority between bus
masters simultaneously requesting the bus must be provided. The 82C89 Bus Arbiter provides several resolving
techniques. All the techniques are based on a priority concept that at a given time one bus master will have priority
above all the rest. There are provisions for using parallel priority resolving techniques, serial priority resolving techniques, and rotating priority techniques.
Parallel Priority Resolving
The parallel priority resolving technique uses a separate bus
request line BREQ for each arbiter on the multi-master system bus, see Figure 1. Each BREQ line enters into a priority
encoder which generates the binary address of the highest
priority BREQ line which is active. The binary address is
BCLK
BREQ
BPRN
1
2
BUSY
3
4
FIGURE 2. HIGHER PRIORITY ARBITER OBTAINING THE BUS
FROM A LOWER PRIORITY ARBITER
NOTES:
1. Higher priority bus arbiter requests the Multi-Master system bus.
2. Attains priority.
3. Lower priority bus arbiter releases BUSY.
4. Higher priority bus arbiter then acquires the bus and pulls BUSY
down.
4-346
82C89
Serial Priority Resolving
The serial priority resolving technique eliminates the need
for the priority encoder-decoder arrangement by daisychaining the bus arbiters together, connecting the higher priority
bus arbiter’s BPRO (Bus Priority Out) output to the BPRN of
the next lower priority. See Figure 3.
BPRN
BUS
ARBITER
BPRO
1
BPRN
BUS
ARBITER BPRO
2
BPRN
BUS
ARBITER BPRO
3
BPRN
BUS
ARBITER BPRO
4
•
•
CBRQ
•
•
BUSY
•
•
FIGURE 3. SERIAL PRIORITY RESOLVING
NOTE: The number of arbiters that may be daisy-chained together
in the serial priority resolving scheme is a function of BCLK and the
propagation delay from arbiter to arbiter. Normally, at 10MHz only 3
arbiters may be daisychained.
Rotating Priority Resolving
The rotating priority resolving technique is similar to that of
the parallel priority resolving technique except that priority is
dynamically re-assigned. The priority encoder is replaced by
a more complex circuit which rotates priority between
requesting arbiters thus allowing each arbiter an equal
chance to use the multi-master system bus, over time.
Which Priority Resolving Technique To Use
There are advantages and disadvantages for each of the
techniques described above. The rotating priority resolving
technique requires substantial external logic to implement
while the serial technique uses no external logic but can
accommodate only a limited number of bus arbiters before the
daisy-chain propagation delay exceeds the multimaster’s system bus clock (BCLK). The parallel priority resolving technique is in general a good compromise between the other two
techniques. It allows for many arbiters to be present on the
bus while not requiring too much logic to implement.
82C89 Modes Of Operation
There are two types of processors for which the 82C89 will
provide support: An Input/Output processor (i.e. an NMOS
8089 IOP) and the 80C86, 80C88. Consequently, there are
two basic operating modes in the 82C89 bus arbiter. One,
the IOB (I/O Peripheral Bus) mode, permits the processor
access to both an I/O Peripheral Bus and a multi-master system bus. The second, the RESB (Resident Bus mode), permits the processor to communicate over both a Resident
Bus and a multi-master system bus. An I/O Peripheral Bus is
a bus where all devices on that bus, including memory, are
treated as I/O devices and are addressed by I/O commands.
All memory commands are directed to another bus, the
multi-master system bus. A Resident Bus can issue both
memory and I/O commands, but it is a distinct and separate
bus from the multi-master system bus. The distinction is that
the Resident Bus has only one master, providing full availability and being dedicated to that one master.
The IOB strapping option configures the 82C89 Bus Arbiter
into the IOB mode and the strapping option RESB configures it into the RESB mode. It might be noted at this point
that if both strapping options are strapped false, the arbiter
interfaces the processor to a multi-master system bus only
(see Figure 4). With both options strapped true, the arbiter
interfaces the processor to a multi-master system bus, a
Resident Bus, and an I/O Bus.
In the IOB mode, the processor communicates and controls
a host of peripherals over the Peripheral Bus. When the I/O
Processor needs to communicate with system memory, it
does so over the system memory bus. Figure 5 shows a possible I/O Processor system configuration.
The 80C86 and 80C88 processors can communicate with a
Resident Bus and a multi-master system bus. Two bus controllers and only one Bus Arbiter would be needed in such a
configuration as shown in Figure 6. In such a system configuration the processor would have access to memory and
peripherals of both busses. Memory mapping techniques are
applied to select which bus is to be accessed. The
SYSB/RESB input on the arbiter serves to instruct the arbiter as to whether or not the system bus is to be accessed.
The signal connected to SYSB/RESB also enables or disables commands from one of the bus controllers. A summary of the modes that the 82C89 has, along with its
response to its status lines inputs, is shown in Table 1.
4-347
82C89
X1
X2
RDY2
82C84A/85
CLOCK
GENERATOR
AEN2
READY RDY1
AEN1
CLK
VCC
XACK MULTI-MASTER
SYSTEM BUS
82C89
BUS
ARBITER
ANYRQST
CLK
IOB
READY
CLK
STATUS (S0, S1, S2)
AEN
82C88
BUS
CONTROLLER
CLK
IOB
ALE
DT/R
DEN
MULTI-MASTER SYSTEM
COMMAND BUS
OE
STB
ADDRESS
LATCH
82C82/
82C83H
(2 OR 3)
MULTI-MASTER SYSTEM
ADDRESS BUS
XCVR
DISABLE
OE
DT/R
TRANSCEIVER
82C86H/
82C87H
(2)
MULTI-MASTER SYSTEM
DATA BUS
FIGURE 4. TYPICAL MEDIUM COMPLEXITY CPU SYSTEM
4-348
MULTI-MASTER SYSTEM BUS
PROCESSOR
LOCAL BUS
VCC
S0-S2 RESB
AEN
80C86
CPU
S0
AD0-AD15 S1
A16-A19 S2
MULTI-MASTER
CONTROL BUS
82C89
AEN1
82C84A/85
CLOCK
RDY1
RDY2
XACK(I/O BUS)
XACK
MULTI-MASTER
SYSTEM BUS
82C89
BUS
ARBITER
READY
CLK
AEN2
CLK
READY
S0-S2
CLK
8089
IOP
I/O BUS
PROCESSOR
LOCAL BUS
OE
STB
ADDRESS
LATCH
82C82/
82C83H
(2 OR 3)
OE
I/O
DATA
BUS
STATUS (S0, S1, S2)
ANYRQST
AEN
AEN
82C88
BUS
CONTROLLER
I/O
COMMAND
BUS
I/O
ADDRESS
BUS
VCC
IOB
RESB
T
TRANSCEIVER
82C86H/
82C87H
(2)
CLK
IOB
ALE
PDEN DEN DT/R
OE
STB
ADDRESS
LATCH
82C82/
82C83H
(2 OR 3)
OE
VCC
MULTI-MASTER
SYSTEM
ADDRESS BUS
XCVR
DISABLE
T
TRANSCEIVER
82C86H/
82C87H
(2)
FIGURE 5. TYPICAL MEDIUM COMPLEXITY IOB SYSTEM
4-349
MULTI-MASTER
SYSTEM
COMMAND BUS
MULTI-MASTER
SYSTEM
DATA BUS
MULTI-MASTER SYSTEM BUS
AD0-AD15 S0
A16-A19 S2
MULTI-MASTER
CONTROL BUS
82C89
AEN2
AEN1
82C84A/85
CLOCK
XACK
RESIDENT BUS
XACK MULTI MASTER
SYSTEM BUS
RDY2 RDY1
READY CLK
READY CLK
STATUS
S0-S2
80C86
CPU
82C89
S0
BUS
S1 ARBITER
S2
MULTI MASTER
SYSTEM BUS CONTROL
RESB
IOB
ANYRQST
SYSB/
RESB
AEN
CLK
AD0-AD15
A16-A19
RESIDENT BUS
AEN
S0-S2
82C88
CLK
RESIDENT
COMMAND BUS
S0-S2
82C88
CLK
MULTI MASTER
SYSTEM COMMAND BUS
DT/R
DT/R
ALE
DEN
DEN
ALE
STB
OE
OE
STB
IOB
PROM
OR
DECODER
OR
CMOS HPL
(NOTE)
RESIDENT
ADDRESS BUS
ADDR
LATCH
82C82/
82C83H
(2 OR 3)
OE
RESIDENT
DATA BUS
ADDR
LATCH
82C82/
82C83H
(2 OR 3)
T
T
MULTI MASTER
SYSTEM ADDRESS BUS
OE
TRANSCEIVER
82C86H/
82C87H
(2)
TRANSCEIVER
82C86H/
82C87H
(2)
MULTI MASTER SYSTEM BUS
CEN
AEN
CEN
VCC
MULTI MASTER
SYSTEM DATA BUS
FIGURE 6. 82C89 BUS ARBITER SHOWN IN SYSTEM - RESIDENT BUS CONFIGURATION
NOTE: By adding another 82C89 arbiter and connecting its AEN to the 82C88 whose AEN is presently grounded, the processor could have
access to two multi-master buses.
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82C89
TABLE 1. SUMMARY OF 82C89 MODES, REQUESTING AND RELINQUISHING THE MULTI-MASTER SYSTEM BUS
SINGLE LINES FROM
80C86 OR 80C88 OR 8088
IOB MODE RESB MODE
IOB = LOW, RESB = HIGH
RESB MODE ONLY
IOB = HIGH, RESB = HIGH
SYSB/RESB =
HIGH
SYSB/RESB =
LOW
SYSB/RESB =
HIGH
SYSB/RESB =
LOW
SINGLE BUS
MODE
IOB = HIGH
RESB = LOW
S2
S1
S0
IOB MODE
ONLY
IOB = LOW
RESB = LOW
I/O
Commands
0
0
0
0
0
1
0
1
0
X
X
X
†
†
†
X
X
X
X
X
X
X
X
X
†
†
†
Halt
0
1
1
X
X
X
X
X
X
Memory
Commands
1
1
1
0
0
1
0
1
0†
†
†
†
†
†
†
X
X
X
†
†
†
X
X
X
†
†
†
Idle
1
1
1
X
X
X
X
X
X
NOTES:
1. X = Multi-Master System Bus is allowed to be Surrendered.
2. † = Multi-Master System Bus is Requested.
MULTI-MASTER SYSTEM BUS
MODE
PIN
STRAPPING
REQUESTED**
SURRENDERED*
Single Bus Multi-Master Mode
IOB = High
RESB = Low
Whenever the processor’s status lines
go active
HLT + TI • CBRQ + HPBRQ ‡
RESB Mode Only
IOB = High
RESB = High
SYSB/RESB + High •
ACTIVE STATUS
(SYSB/RESB = Low + TI) •
CBRQ + HLT + HPBRQ
IOB Mode Only
IOB = Low
RESB = Low
Memory Commands
(I/O Status + TI) • CBRQ + HLT +
HPBRQ
IOB Mode RESB Mode
IOB = Low
RESB = High
(Memory Command) •
(SYSB/RESB = High)
(I/O Status Commands) +
SYSB/RESB = Low) • CBRQ +
HPBRQ + HLT
NOTES:
* LOCK prevents surrender of Bus to any other arbiter, CRQLCK prevents surrender of Bus to any lower priority arbiter.
** Except for HALT and Passive or IDLE Status.
‡ HPBRQ, Higher priority Bus request or BPRN = 1.
1. IOB Active Low.
2. RESB Active High.
3. + is read as “OR” and • as “AND”
4. TI = Processor Idle Status S2, S1, S0 = 111
5. HLT = Processor Halt Status S2, S1, S0 = 011
4-351
82C89
Absolute Maximum Ratings
Thermal Information
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +8.0V
Input, Output or I/O Voltage . . . . . . . . . . . GND -0.5V to VCC +0.5V
ESD Classification . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Class 1
Thermal Resistance
θJA (oC/W) θJC (oC/W)
CERDIP Package . . . . . . . . . . . . . . . .
80
20
CLCC Package . . . . . . . . . . . . . . . . . .
90
24
PDIP Package . . . . . . . . . . . . . . . . . . .
75
N/A
PLCC Package . . . . . . . . . . . . . . . . . .
75
N/A
Storage Temperature Range . . . . . . . . . . . . . . . . . .-65oC to +150oC
Maximum Junction Temperature
Ceramic Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +175oC
Plastic Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . +150oC
Maximum Lead Temperature (Soldering 10s) . . . . . . . . . . . . +300oC
(PLCC - Lead Tips Only)
Operating Conditions
Operating Voltage Range . . . . . . . . . . . . . . . . . . . . . +4.5V to +5.5V
Operating Temperature Range
C82C89. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 0oC to +70oC
I82C89 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -40oC to +85oC
M82C89 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . -55oC to +125oC
Die Characteristics
Gate Count . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 200 Gates
CAUTION: Stresses above those listed in “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress only rating and operation
of the device at these or any other conditions above those indicated in the operational sections of this specification is not implied.
DC Electrical Specifications
SYMBOL
VCC = 5.0V ± 10%;
TA = 0oC to +70oC (C82C89);
TA = -40oC to +85oC (I82C89);
TA = -55oC to +125oC (M82C89)
PARAMETER
MIN
MAX
UNITS
TEST CONDITIONS
VIH
Logical One Input Voltage
2.0
2.2
-
V
V
C82C89, I82C89
M82C89, Note 1
VIL
Logical Zero Input Voltage
-
0.8
V
Note 1
VIHC
CLK Logical One Input Voltage
0.7 VCC
-
V
VILC
CLK Logical Zero Input Voltage
-
0.2 VCC
V
VOL
Output Low Voltage
BUSY, CBRQ
AEN
BPRO, BREQ
-
0.45
0.45
0.45
V
V
V
IOL = 20mA
IOL = 16mA
IOL = 8mA
VOH1
Output High Voltage
BUSY, CBRQ
VOH2
Output High Voltage
All Other Outputs
Open-Drain
3.0
VCC -0.4
-
V
V
IOH = -2.5mA
IOH = -100µA
II
Input Leakage Current
-1.0
1.0
µA
VIN = GND or VCC, DIP Pins 1-6, 9, 14-19
IO
I/O Leakage
-10.0
10.0
µA
VO = GND or VCC, DIP Pins 11-12
VCC = 5.5V, VIN = VCC or GND, Outputs Open
ICCSB
Standby Power Supply
-
10
µA
ICCOP
Operating Power Supply Current
-
1
mA/MHz
VCC = 5.5V, Outputs Open, Note 2
NOTES:
1. Does not apply to IOB, RESB, or ANYRQST. These are strap options and should be held to VCC or GND.
2. Maximum current defined by CLK or BCLK, whichever has the highest operating frequency
Capacitance
SYMBOL
CIN
COUT
CIO
TA = +25oC
PARAMETER
TYPICAL
UNITS
TEST CONDITIONS
Input Capacitance
10
pF
FREQ = 1MHz, all measurements are
referenced to device GND
Output Capacitance
10
pF
I/O Capacitance
15
pF
4-352
82C89
AC Electrical Specifications
SYMBOL
VCC = 5.0V ± 10%; GND = 0V:
TA = 0oC to +70oC (C82C89);
TA = -40oC to +85oC (I82C89);
TA = -55oC to +125oC (M82C89)
PARAMETER
MIN
MAX
UNIT
TEST CONDITIONS
(1)
TCLCL
CLK Cycle Period
125
-
ns
Note 3
(2)
TCLCH
CLK Low Time
55
-
ns
Note 3
(3)
TCHCL
CLK High Time
35
-
ns
Note 3
(4)
TSVCH
Status Active Setup
65
TCLCL-10
ns
Note 3
(5)
TSHCL
Status Inactive Setup
50
TCLCL-10
ns
Note 3
(6)
THVCH
Status Inactive Hold
10
-
ns
Note 3
(7)
THVCL
Status Active Hold
10
-
ns
Note 3
(8)
TBYSBL
BUSY↓↑ Setup to BCLK↓
20
-
ns
Note 3
(9)
TCBSBL
CBRQ↓↑ Setup to BCLK↓
20
-
ns
Note 3
(10)
TBLBL
BCLK Cycle Time
100
-
ns
Note 3
(11)
TBHCL
BCLK High Time
30
0.65
(TBLBL)
ns
Note 3
(12)
TCLLL1
LOCK Inactive Hold
10
-
ns
Note 3
(13)
TCLLL2
LOCK Active Setup
40
-
ns
Note 3
(14)
TPNBL
BPRN↓↑ to BCLK Setup Time
20
-
ns
Note 3
(15)
TCLSR1
SYSB/RESB Setup
0
-
ns
Note 3
(16)
TCLSR2
SYSB/RESB Hold
30
-
ns
Note 3
(17)
TIVIH
Initialization Pulse Width
675
-
ns
Note 3
(18)
TBLBRL
BCLK to BREQ Delay↓↑
-
35
ns
Note 3
(19)
TBLPOH
BCLK to BPRO↓↑
-
35
ns
Note 1 and 3
(20)
TPNPO
BPRN↓↑ to BPRO↓↑ Delay
-
22
ns
Note 1 and 3
(21)
TBLBYL
BCLK to BUSY Low
-
60
ns
Note 3
(22)
TBLBYH
BCLK to BUSY Float
-
35
ns
Note 2 and 3
(23)
TCLAEH
CLK to AEN High
-
65
ns
Note 3
(24)
TBLAEL
BCLK to AEN Low
-
40
ns
Note 3
(25)
TBLCBL
BCLK to CBRQ Low
-
60
ns
Note 3
(26)
TBLCBH
BCLK to CBRQ Float
-
40
ns
Note 2 and 3
(27)
TOLOH
Output Rise Time
-
20
ns
From 0.8V to 2.0V, Note 4
(28)
TOHOL
Output Fall Time
-
12
ns
From 2.0V to 0.8V, Note 4
(29)
TILIH
Input Rise Time
-
20
ns
From 0.8V to 2.0V
(30)
TIHIL
Input Fall Time
-
20
ns
From 2.0V to 0.8V
NOTES:
1. BCLK generates the first BPRO wherein subsequent BPRO changes lower in the chain are generated through BPRON.
2. Measured at 0.5V above GND.
3. All AC parameters tested as per AC test load circuits. Input rise and fall times are driven at 1ns/V.
4. Except BUSY and CBRQ
4-353
82C89
AC Test Load Circuits
BUSY, CBRQ LOAD CIRCUIT
AEN LOAD CIRCUIT
2.5V
2.9V
102Ω
OUTPUT FROM
DEVICE
UNDER TEST
BPRO, BREQ LOAD CIRCUIT
2.9V
157.2Ω
TEST
POINT
OUTPUT FROM
DEVICE
UNDER TEST
TEST
POINT
100pF
(NOTE)
100pF
(NOTE)
249.6Ω
OUTPUT FROM
DEVICE
UNDER TEST
TEST
POINT
100pF
(NOTE)
NOTE: Includes Stray and Jig Capacitance
AC Testing Input, Output Waveform
INPUT
OUTPUT
VIH +0.4V
VOH
1.5V
VIL -0.4V
1.5V
AC Testing: Inputs are driven at VIH +0.4V for a logic “1” and VIL
-0.4V for a logic “0”. The clock is driven at VCC -0.4V and 0.4V. Timing measurements are made at 1.5V for both a logic “1” and “0”.
VOL
4-354
82C89
Timing Waveform
STATE
T4
(1)
T1
TCLCL
T2
T4
TCLCH
(2)
CLK
(6)
THVCH
S2, S1, S0
T3
(12)
TCLLL1
TSVCH
(4)
TCHCL
(3)
TSHCL (5)
THVCL
(7)
TCLL2
(13)
LOCK
(SEE NOTE 1)
(SEE
NOTE 2)
(SEE NOTE 2)
SYSB/RESB
TCLSR1 (15)
(16)
TCLSR2
AEN
(SEE NOTE 3)
(24)
TBLAEL
PROCESSOR CLK RELATED
BUS CLK RELATED
(11)
TBHCL
(23)
TCLAEH
TBLBL
(10)
BCLK
(18) TBLBRL
BREQ #2
TBLPOH (19)
BPRN #2
(14)
TPNBL
(BPRO #1)
BPRO #2
(20)
TPnPO
(BPRN #3)
TBYSBL (8)
BUSY
TBLBYL (21)
(25) TBLCBL
CBRQ
TBLBYH
(22)
(26) TBLCBH
TCBSBL (9)
NOTES:
1. LOCK active can occur during any state, as long as the relationships shown above with respect to the CLK are maintained. LOCK inactive
has no critical time and can be asynchronous. CRQLCK has no critical timing and is considered an asynchronous input signal.
2. Glitching of SYSB/RESB is permitted during this time. After θ2 of T1, and before θ1 of T4, SYSB/RESB should be stable to maintain system efficiency.
3. AEN leading edge is related to BCLK, trailing edge to CLK. The trailing edge of AEN occurs after bus priority is lost.
ADDITIONAL NOTES:
The signals related to CLK are typical processor signals, and do not relate to the depicted sequence of events of the signals referenced to
BCLK. The signals shown related to the BCLK represent a hypothetical sequence of events for illustration. Assume 3 bus arbiters of priorities 1, 2 and 3 configured in serial priority resolving scheme (as shown in Figure 3). Assume arbiter 1 has the bus and is holding BUSY low.
Arbiter #2 detects its processor wants the bus and pulls low BREQ #2. If BPRN #2 is high (as shown), arbiter #2 will pull low CBRQ line.
CBRQ signals to the higher priority arbiter #1 that a lower priority arbiter wants the bus. [A higher priority arbiter would be granted BPRN
when it makes the bus request rather than having to wait for another arbiter to release the bus through CBRQ]. *Arbiter #1 will relinquish the
multi-master system bus when it enters a state not requiring it (see Table 1), by lowering its BPRO #1 (tied to BPRN #2) and releasing BUSY.
Arbiter #2 now sees that is has priority from BPRN #2 being low and releases CBRQ. As soon as BUSY signifies the bus is available (high),
arbiter #2 pulls BUSY low on next falling edge of BCLK. Note that if arbiter #2 didn’t want the bus at the time it received priority, it would pass
priority to the next lower priority arbiter by lowering its BPRO #2 [TPNPO].
Note that even a higher priority arbiter which is acquiring the bus through BPRN will momentarily drop CBRQ until it has acquired the bus.
4-355
82C89
Burn-In Circuits
MD82C89 CERDIP
VCC
C1
R2
F7
R2
F13
1
20
2
19
R2
F6
R2
R2
3
F14
18
F5
R2
R2
4
F12
17
F0
R2
F0
R2
5
16
6
15
7
14
F9
R1
VCC
VCC/2
R2
F10
R1
R2
F11
R1
R1
8
13
9
12
R2
F8
R1
VCC/2
R1
10
11
MR82C89 CLCC
VCC
F14 F13 F7
F6
R2 R2 R2
3
F12
F0
VCC
R2
R2
R1
2
1
C1
R2
20 19
R2
4
18
5
17
6
16
7
15
8
14
R1
VCC/ 2
R1
10 11 12 13
9
R2
F8
R1 R1 R1
VCC/ 2
NOTES:
1. VCC = 5.5V ± 0.5V, GND = 0V
2. VIH = 4.5V ± 10%, VIL = -0.2V to +0.4V
3. Components Values:
R1 = 1.2kΩ, 1/4W, 5%
R2 = 47kΩ, 1/4W, 5%
C1 = 0.01µF minimum
F0 = 100kHz ± 10%
F1 = F0/2
F2 = F1/2. . . .
F14 = F13/2
4-356
F5
R2
R2
F0
F9
R2
F10
R2
F11
82C89
Die Characteristics
DIE DIMENSIONS:
92.9 x 95.7 x 19 ± 1mils
GLASSIVATION:
Type: Nitrox
Thickness: 10kÅ ± 2kÅ
METALLIZATION:
Type: Si - Al
Thickness: 11kÅ ± 2kÅ
WORST CASE CURRENT DENSITY:
1.8 x 105 A/cm2
Metallization Mask Layout
S0
S1
VCC
S2
IOB
SYSB/RESB
82C89
RESB
CLK
BCLK
ANYRQST
LOCK
INIT
CRQLCK
ANYRQST
AEN
CBRQ
BUSY
GND
BPRN
BPRO
BREQ
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Intersil products are sold by description only. Intersil Corporation reserves the right to make changes in circuit design and/or specifications at any time without
notice. Accordingly, the reader is cautioned to verify that data sheets are current before placing orders. Information furnished by Intersil is believed to be accurate
and reliable. However, no responsibility is assumed by Intersil or its subsidiaries for its use; nor for any infringements of patents or other rights of third parties which
may result from its use. No license is granted by implication or otherwise under any patent or patent rights of Intersil or its subsidiaries.
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4-357
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