ETC UT1760A-GC

UTI760A RTS Remote Terminal for Stores
FEATURES
❐ Complete MIL-STD-1760A Notice I through III
❐
❐
❐
❐
❐
❐
❐
remote terminal interface
1K x 16 of on-chip static RAM for message data,
completely accessible to host
Self-test capability, including continuous loop-back
compare
Programmable memory mapping via pointers for
efficient use of internal memory, including buffering
multiple messages per subaddress
RT-RT Terminal Address Compare
Command word stored with incoming data for
enhanced data management
User selectable RAM Busy (RBUSY) signal for slow
or fast processor interfacing
Full military operating temperature range, -55°C to
+125°C, screened to the specific test methods listed in
OUT
IN
OUT
IN
OUTPUT MULTIPLEXING AND
SELF-TEST WRAPAROUND LOGIC
MCSA(4:0)
MODE CODE/
SUBADDRESS
❐
Table I of MIL-STD-883, Method 5004, Class B, also
Standard Military Drawing available
Available in 68-pin pingrid array package
INTRODUCTION
The UT1760A RTS is a monolithic CMOS VLSI solution
to the requirements of the dual-redundant MIL-STD-1553B
interface as specified by MIL-STD-1760A. Designed to
reduce cost and space in the mission stores interface, the
RTS integrates the remote terminal logic with a userconfigured 1K x 16 static RAM. In addition, the RTS has a
flexible subsystem interface to permit use with most
processors or controllers.
The RTS provides all protocol, data handling, error
checking, and memory control functions, as well as
comprehensive self-test capabilities. The RTS’s memory
meets all of a mission store’s message storage needs through
user-defined memory mapping. This memory-mapped
architecture allows multiple message buffering at
RTA(4:0)
REMOTE TERMINAL
ADDRESS
CONTROL
INPUTS
STATUS
OUTPUTS
COMMAND
RECOGNITION
DECODER
CONTROL AND
ERROR LOGIC
1K X 16 RAM
DECODER
ADDR(9:0)
MUX
PTR REGISTER
ENCODER
DATA(15:0)
CLOCK AND RESET 12MHz
LOGIC
RESET
2MHz
Figure 1. UT1760A RTS Functional Block Diagram
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Table of Contents
1.0
ARCHITECTURE AND OPERATION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .3
1.1 Memory Map and Host Memory Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . 3
1.2 RTS RAM Pointer Structure . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4
1.3 Internal Register Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5
1.4 Mode Code and Subaddress . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8
1.5 MIL-STD-1760A Subaddress and Mode Code Definitions . . . . . . . . . . . . . . . 9
1.6 Terminal Address . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
1.7 Internal Self-Test . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
1.8 Power-up and Master Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
1.9 Encoder and Decoder . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
1.10 RT-RT Transfer Compare . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .12
1.11 Illegal Command Decoding . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13
2.0
MEMORY MAP EXAMPLE . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .13
3.0
PIN IDENTIFICATION AND DESCRIPTION . . . . . . . . . . . . . . . . . . . . . . . . . . .16
4.0
MAXIMUM AND RECOMMENDED OPERATING CONDITIONS22
5.0
DC ELECTRICAL CHARACTERISTICS. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .23
6.0
AC ELECTRICAL CHARACTERISTICS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .24
7.0
PACKAGE OUTLINE DRAWING . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .35
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1.0 ARCHITECTURE AND OPERATION
The UT1760A RTS is an interface device linking a MILSTD-1553 serial data bus and a host microprocessor system.
The RTS’s MIL-STD-1553B interface includes encoding/
decoding logic, error detection, command recognition, 1K
x 16 of SRAM, pointer registers, clock, and reset circuits.
Illegal subaddress circuitry makes the RTS MIL-STD1760A-specific.
1.1 Memory Map and Host Memory Interface
The host can access the 1K x 16 RAM memory like a
standard RAM device through the 10-bit address and 16-bit
data buses. The host uses the Chip Select (CS), Read/Write
(RD/WR), and Output Enable (OE) signals to control data
transfer to and from memory. When the RTS requires access
to its own internal RAM, it asserts the RBUSY signal to
alert the host. The RBUSY signal is programmable via the
internal Control Register to be asserted either 5.7ms or
2.7ms prior to the RTS needing access to its internal RAM.
The RTS stores MIL-STD-1760A messages in 1K x 16 of
on-chip RAM. For efficient use of the 1K x 16 memory on
the RTS, the host programs a set of pointers to map where
the 1760A message is stored. The RTS uses the upper 64
words (address 3C0 (hex) through 3FF (hex)) as pointers.
The RTS provides pointers for all 30 receive subaddresses,
all 30 transmit subaddresses, and four mode code
commands with associated data words as defined in
MIL-STD-1553B. The remaining 960 words of memory
contain receive, transmit, and mode code data in a
host-defined structure.
RTS Memory Map
000 (hex)
Message
Storage
Locations
3BF(hex)
15 MSB
Receive
Message
Pointers
0 LSB
XMIT VECTOR WORD MODE CODE (W/DATA)
RCV SUBADDRESS 01
3C0 (hex)
3C1 (hex)
(3C1 TO 3DE)
RCV SUBADDRESS 30
SYNCHRONIZE MODE CODE (W/DATA)
15 MSB
Transmit
Message
Pointers
3DE (hex)
3DF (hex)
0 LSB
XMIT LAST COMMAND MODE CODE (W/DATA)
XMT SUBADDRESS 01
3E0 (hex)
3E1 (hex)
(3E1 TO 3FE)
XMT SUBADDRESS 30
XMT BIT WORD MODE CODE (W/DATA)
15 MSB
3FE (hex)
3FF (hex)
0 LSB
Figure 2. RTS Memory Map
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MESSAGE INDEX
15 (MSB)
MESSAGE DATA ADDRESS
10
9
Message Index:
Defines the maximum
messages buffered for the
given subaddress.
0 (LSB)
Message Data Address:
Indicates the starting memory
address for incoming message
storage.
Figure 3. Message Pointer Structure
1.2 RTS RAM Pointer Structure
The RAM 16-bit pointers have a 6-bit index field and a
10-bit address field. The 6-bit index field allows for the
storage of up to 64 messages per subaddress. A message
consists of the 1553 command word and its associated
data words.
The 16-bit pointer for Transmit Last Command Mode Code
is located at memory location 3E0 (hex). The Transmit Last
Command Mode Code pointer buffers up to 63 command
words. An example of command word storage follows:
Example:
3E0 (hex)
Contents = FC00 (hex)
11 1111 00 0000 0000
Address Field = 000 (hex)
Index Field = 3F (hex)
First command word storage location (3E0 = F801):
Address Field = 001 (hex)
Index Field = 3E (hex)
Sixty-third command word storage location
(3E0 = 003F):
Address Field = 03F (hex)
Index Field = 00 (hex)
Sixty-fourth command word storage location (3E0 = 003F)
(previous command word overwritten):
Address Field = 03F (hex)
Index Field = 00 (hex)
The Transmit Last Command Mode Code has Address Field
boundary conditions for the location of command word
buffers. The host can allocate a maximum 63 sequential
locations following the Address Field starting address. For
proper operation, the Address Field must start on an I x 40
(hex) address boundary, where I is greater than or equal to
zero and less than or equal to 14. A list of valid Index and
Address Fields follows:
I
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
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Valid Index Fields
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
3F (hex) to 00 (hex)
Valid Address Fields
000 (hex) to 03F(hex)
040 (hex) to 07F (hex)
080 (hex) to 0BF(hex)
0C0 (hex) to 0FF (hex)
100 (hex) to 13F (hex)
140 (hex) to 17F (hex)
180 (hex) to 1BF (hex)
1C0 (hex) to 1FF (hex)
200 (hex) to 23F (hex)
240 (hex) to 27F (hex)
280 (hex) to 2BF (hex)
2C0 (hex) to 2FF (hex)
300 (hex) to 33F (hex)
340 (hex) to 37F (hex)
380 (hex) to 3BF (hex)
Subaddress/Mode Code
Transmit Vector Word Mode Code
Receive Subaddress
01
Receive Subaddress
02
Receive Subaddress
03
Receive Subaddress
04
Receive Subaddress
05
Receive Subaddress
06
Receive Subaddress
07
Receive Subaddress
08
Receive Subaddress
09
Receive Subaddress
10
Receive Subaddress
11
Receive Subaddress
12
Receive Subaddress
13
Receive Subaddress
14
Receive Subaddress
15
Receive Subaddress
16
Receive Subaddress
17
Receive Subaddress
18
Receive Subaddress
19
Receive Subaddress
20
Receive Subaddress
21
Receive Subaddress
22
Receive Subaddress
23
Receive Subaddress
24
Receive Subaddress
25
Receive Subaddress
26
Receive Subaddress
27
Receive Subaddress
28
Receive Subaddress
29
Receive Subaddress
30
Synchronize w/Data Word Mode Code
RAM Location
3C0 (hex)
3C1 (hex)
3C2 (hex)
3C3 (hex)
3C4 (hex)
3C5 (hex)
3C6 (hex)
3C7 (hex)
3C8 (hex)
3C9 (hex)
3CA (hex)
3CB (hex)
3CC (hex)
3CD (hex)
3CE (hex)
3CF (hex)
3D0 (hex)
3D1 (hex)
3D2 (hex)
3D3 (hex)
3D4 (hex)
3D5 (hex)
3D6 (hex)
3D7 (hex)
3D8 (hex)
3D9 (hex)
3DA (hex)
3DB (hex)
3DC (hex)
3DD (hex)
3DE (hex)
3DF (hex)
1.3 Internal Registers
The RTS uses two internal registers to allow the host to
control the RTS operation and monitor its status. The host
uses the Control (CTRL) signal along with Chip Select (CS),
Read/Write (RD/WR), and Output Enable (OE) to read the
16-bit Status Register or write to the 13-bit Control Register.
No address data is needed to select a register. The Control
Register toggles bits in the MIL-STD-1553B status word,
Subaddress/Mode Code
Transmit Last Command Mode Code
Transmit Subaddress
01
Transmit Subaddress
02
Transmit Subaddress
03
Transmit Subaddress
04
Transmit Subaddress
05
Transmit Subaddress
06
Transmit Subaddress
07
Transmit Subaddress
08
Transmit Subaddress
09
Transmit Subaddress
10
Transmit Subaddress
11
Transmit Subaddress
12
Transmit Subaddress
13
Transmit Subaddress
14
Transmit Subaddress
15
Transmit Subaddress
16
Transmit Subaddress
17
Transmit Subaddress
18
Transmit Subaddress
19
Transmit Subaddress
20
Transmit Subaddress
21
Transmit Subaddress
22
Transmit Subaddress
23
Transmit Subaddress
24
Transmit Subaddress
25
Transmit Subaddress
26
Transmit Subaddress
27
Transmit Subaddress
28
Transmit Subaddress
29
Transmit Subaddress
30
Transmit Bit Word Mode Code
RAM Location
3E0 (hex)
3E1 (hex)
3E2 (hex)
3E3 (hex)
3E4 (hex)
3E5 (hex)
3E6 (hex)
3E7 (hex)
3E8 (hex)
3E9 (hex)
3EA (hex)
3EB (hex)
3EC (hex)
3ED (hex)
3EE (hex)
3EF (hex)
3F0 (hex)
3F1 (hex)
3F2 (hex)
3F3 (hex)
3F4 (hex)
3F5 (hex)
3F6 (hex)
3F7 (hex)
3F8 (hex)
3F9 (hex)
3FA (hex)
3FB (hex)
3FC (hex)
3FD (hex)
3FE (hex)
3FF (hex)
enables the biphase inputs, recognizes broadcast
commands, selects Notice I and II or III, determines RAM
Busy (RBUSY) timing, selects disconnect or terminal active
flag, and puts the part in self-test mode. The Status Register
supplies operational status of the UT1760A RTS to the host.
These registers must be initialized before attempting RTS
operation. Internal registers can be accessed while RBUSY
is active.
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Control Register (Write Only)
The 13-bit write-only Control Register manages the operation of the RTS. Write to the Control Register by applying a logic
one to OE, and a logic zero to CTRL, CS, and RD/WR. Data is loaded into the Control Register via I/O pins DATA(12:0).
Control register write must occur 50ns before the rising edge of COMSTR to latch data into the outgoing status word.
Bit
Number
Bit 0
Bit 1
Bit 2
Bit 3
Initial
Condition
[1]
[1]
[0]
[1]
Description
Channel A Enable. A logic 1 enables Channel A biphase inputs.
Channel B Enable. A logic 1 enables Channel B biphase inputs.
Terminal Flag. A logic 1 sets the Terminal Flag bit of the Status Word.
System Busy. A logic 1 sets the Busy bit of the Status Word and limits RTS access to the
memory. No data word can be retrieved or stored; command words will be stored.
Bit 4
[0]
Subsystem Busy. A logic 1 sets the Subsystem Flag bit of the Status Word.
Bit 5
[0]
Self-Test Channel Select. This bit selects which channel the self-test checks; a logic 1 selects
Channel A and a logic 0 selects Channel B.
Bit 6
[0]
Self-Test Enable. A logic 1 places the RTS in the internal self-test mode and inhibits normal
operation. Channels A and B should be disabled if self-test is chosen.
Bit 7
[0]
Service Request. A logic 1 sets the Service Request bit of the Status Word.
Bit 8
[0]
Instrumentation. A logic 1 sets the Instrumentation bit of the Status Word.
Bit 9
[1]
Broadcast Enable. A logic 1 enables the RTS to recognize broadcast commands.
Bit 10
[1]
Notice Select. A logic 1 enables Notice III operation; logic 0 enables Notice I or II operation.
Bit 11
[1]
DSCNCT/TERACT Pin Select. A logic 1 selects the “Disconnect” function; a logic 0 selects
the “Terminal Active” function.
Bit 12
[1]
RBUSY Time Select. A logic 1 selects a 5.7µs RBUSY alert; a logic 0 selects a 2.7µs
RBUSY alert.
[] - Values in parentheses indicate the initialized values of these bits.
CONTROL REGISTER (WRITE ONLY):
X
X
X RBUSY PS
TS
NO
TICE
[1]
[1]
[1]
BCEN INS SRQ ITST ITCS SUBS BUSY TF
CH B CH A
EN
EN
[1]
[1]
[0]
[0]
[0]
MSB
[ ] defines reset state
Figure 4a. Control Register
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RTS-6
[0]
[0]
[1]
[0]
[1]
LSB
Status Register (Read Only):
The 16-bit read-only Status Register provides the RTS system status. Read the Status Register by applying a logic 0 to CTRL,
CS, and OE, and a logic 1 to RD/WR. The 16-bit contents of the Status Register are read from data I/O pins DATA(15:0).
Bit
Number
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Initial
Condition
Description
[0]
[0]
[0]
[0]
[0]
[0]
MCSA0. The LSB of the mode code or subaddress as indicated by the logic state of bit 5.
MCSA1. Mode code or subaddress as indicated by the logic state of bit 5.
MCSA2. Mode code or subaddress as indicated by the logic state of bit 5.
MCSA3. Mode code or subaddress as indicated by the logic state of bit 5.
MCSA4. Mode code or subaddress as indicated by the logic state of bit 5.
MC/SA. A logic 1 indicates that bits 4 through 0 are the subaddress of the last command word,
and that the last command word was a normal transmit or receive command. A logic 0 indicates
that bits 4 through 0 are a mode code, and that the last command was a mode command.
Bit 6
[1]
Channel A/B. A logic 1 indicates that the most recent command arrived on Channel A; a logic 0
indicates that it arrived on Channel B.
Bit 7
[1]
Channel B Enabled. A logic 1 indicates that Channel B is available for both reception and
transmission.
Bit 8
[1]
Channel A Enabled. A logic 1 indicates that Channel A is available for both reception and
transmission.
Bit 9
[1]
Terminal Flag Enabled. A logic 1 indicates that the Bus Controller has not issued an Inhibit
Terminal Flag Mode Code. A logic 0 indicates that the Bus Controller, via the above mode
code, is overriding the host system’s ability to set the Terminal Flag bit of the status word.
Bit 10
[1]
Busy. A logic 1 indicates the Busy bit is set. This bit is reset when the System Busy bit in the
Control Register is reset.
Bit 11
[0]
Self-Test. A logic 1 indicates that the chip is in the internal self-test mode. This bit is reset
when the self-test is terminated.
Bit 12
[0]
TA Parity Error. A logic 1 indicates the wrong Terminal Address parity; it causes the biphase
inputs to be disabled. TA Parity Error results in the Message Error bit being set to a logic one,
and Channels A and B become disabled.
Bit 13
[0]
Message Error. A logic 1 indicates that a message error has occurred since the last Status Register read. This bit is not reset until the Status Register has been examined. Message error condition must be removed before reading the Status Register to reset the Message Error bit.
Bit 14
[0]
Valid Message. A logic 1 indicates that a valid message has been received since the last Status
Register read. This bit is not reset until the Status Register has been examined.
Bit 15
[0]
Terminal Active. A logic 1 indicates the device is executing a transmit or receive operation.
Same as TERACT output except active high. (Always TERACT; never DSCNCT.)
[] - Values in parentheses indicate the initialized values of these bits.
STATUS REGISTER (READ ONLY):
TERM VAL MESS TAPA SELF- BUSY TFEN CH A CH B CHNL MC/ MCSA MCSA MCSA MCSA MCSA
ACTV MESS ERR ERR TEST
EN
EN
A/B
SA
4
3
2
1
0
[0]
[0]
MSB
[0]
[0]
[0]
[1]
[1]
[1]
[1]
[1]
[0]
[0]
[0]
[0]
[0]
[0]
LSB
[ ] defines reset state
Figure 4b. Status Register
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RTS-7
1.4 Mode Code and Subaddress
The UT1760A RTS provides two modes of illegal
subaddress decoding, one meeting MIL-STD-1760A
Notices I and II, and the other meeting MIL-STD-1760A
Notice III. In addition, the device has automatic internal
illegal command decoding for reserved MIL-STD-1553B
mode codes. These definitions are extracted from MILSTD-1760A and reviewed in section 1.5 of this document.
Upon command word validation and decode, status pins
MCSA(4:0) and MC/SA become valid. Status pin MC/SA
will indicate whether the data on pins MCSA(4:0) is mode
code or subaddress information. Status Register bits 0
through 5 contain the same information as pins MCSA(4:0)
and MC/SA. The system designer can use signals
MCSA(4:0), MC/SA, BRDCST, RTRT, etc. to illegalize
mode codes, subaddresses, and other message formats
(broadcast and RT-to-RT) via the Illegal Command
(ILLCOM) input to the part.
RTS MODE CODE HANDLING PROCEDURE
T/R
Mode Code
Function
0
10100
Selected Transmitter Shutdown 2
0
10101
Override Selected Transmitter
Shutdown 2
0
10001
Synchronize (w/Data)
1
00000
Dynamic Bus Control 2
1
00001
Synchronize 1
1
00010
Transmit Status Word 3
1
00011
Initiate Self-Test 1
1
00100
Transmitter Shutdown
1
00101
Override Transmitter Shutdown
1
00110
Inhibit Terminal Flag Bit
1
00111
Override Inhibit Terminal Flag
1
01000
Reset Remote Terminal 1
1
10010
1
10000
Transmit Last Command
Word 3
Transmit Vector Word
1
10011
Transmit BIT Word
Operation
1. Command word stored
2. MERR pin asserted
3. MERR bit set in Status Register
4. Status word transmitted
1. Command word stored
2. MERR pin asserted
3. MERR bit set in Status Register
4. Status word transmitted
1. Command word stored
2. Data word stored
3. Status word transmitted
1. Command word stored
2. MERR pin asserted
3. MERR bit set in Status Register
4. Status word transmitted
1. Command word stored
2. Status word transmitted
1. Command word stored
2. Status word transmitted
1. Command word stored
2. Status word transmitted
1. Command word stored
2. Alternate bus shutdown
3. Status word transmitted
1. Command word stored
2. Alternate bus enabled
3. Status word transmitted
1. Command word stored
2. Terminal Flag bit set to zero and disabled
3. Status word transmitted
1. Command word stored
2. Terminal Flag bit enabled, but not set to logic one
3. Status word transmitted
1. Command word stored
2. Status word transmitted
1. Status word transmitted
2. Last command word transmitted
1. Command word stored
2. Status word transmitted
3. Data word transmitted
1. Command word stored
2. Status word transmitted
3. Data word transmitted
Notes:
1. Further host interaction required for mode code operation.
2. Reserved mode code; A) MERR pin asserted, B) MESS ERR bit set, C) status word transmitted (ME bit set to logic one).
3. Status word not affected.
4. Undefined mode codes are treated as reserved mode codes.
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RTS-8
1.5 MIL-STD-1760A Subaddress and Mode Code Definitions
Table 1. Subaddress and Mode Code Definitions Per MIL-STD-1760A Notice I
Subaddress Field
Binary (Decimal)
00000 (00)
00001 (01)
00010 (02)
00011 (03)
00100 (04)
00101 (05)
00110 (06)
00111 (07)
01000 (08)
01001 (09)
01010 (10)
01011 (11)
01100 (12)
01101 (13)
01110 (14)
01111 (15)
10000 (16)
10001 (17)
10010 (18)
10011 (19)
10100 (20)
10101 (21)
10110 (22)
10111 (23)
11000 (24)
11001 (25)
11010 (26)
11011 (27)
11100 (28)
11101 (29)
11110 (30)
11111 (31)
Message Format
Receive
1
B.40.1.1.3
Reserved B.40.2.1 2
User Defined
Reserved
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
Reserved
User Defined
User Defined
User Defined
Reserved
User Defined
Reserved
User Defined
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
B.40.1.1.3
Transmit
B.40.1.1.3
Store Description
User Defined
Reserved
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
B.40.1.1.3
Description
Mode Code Indicator
Nuclear Weapon
Nuclear Weapon
Mode Code Indicator
Notes:
1. Refer to section B.40.1.1.3 of the MIL-STD-1760A specification for definition.
2. Refer to section B.40.2.1 of the MIL-STD-1760A specification for definition.
3. Reserved subaddresses illegalized; Message Error bit and pin set; SW transmitted.
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RTS-9
Table 2. Subaddress and Mode Code Definitions Per MIL-STD-1760A Notice II
Subaddress Field
Binary (Decimal)
00000 (00)
00001 (01)
00010 (02)
00011 (03)
00100 (04)
00101 (05)
00110 (06)
00111 (07)
01000 (08)
01001 (09)
01010 (10)
01011 (11)
01100 (12)
01101 (13)
01110 (14)
01111 (15)
10000 (16)
10001 (17)
10010 (18)
10011 (19)
10100 (20)
10101 (21)
10110 (22)
10111 (23)
11000 (24)
11001 (25)
11010 (26)
11011 (27)
11100 (28)
11101 (29)
11110 (30)
11111 (31)
Message Format
Receive
1
B.40.1.1.3
Reserved B.40.2.1 2
User Defined
Reserved
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
Reserved
User Defined
User Defined
User Defined
Reserved
User Defined
Reserved
User Defined
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
B.40.1.1.3
Transmit
B.40.1.1.3
Store Description
User Defined
Reserved
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
User Defined
B.40.1.1.3
Notes:
1. Refer to section B.40.1.1.3 of the MIL-STD-1760A specification for definition.
2. Refer to section B.40.2.1 of the MIL-STD-1760A specification for definition.
3. Reserved subaddresses illegalized; Message Error bit and pin set; SW transmitted.
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RTS-10
Description
Mode Code Indicator
Nuclear Weapon
Nuclear Weapon
Mode Code Indicator
Table 3. Subaddress and Mode Code Definitions Per MIL-STD-1760A Notice III
Subaddress Field
Binary (Decimal)
00000 (00)
00001 (01)
00010 (02)
00011 (03)
00100 (04)
00101 (05)
00110 (06)
00111 (07)
01000 (08)
01001 (09)
01010 (10)
01011 (11)
01100 (12)
01101 (13)
01110 (14)
01111 (15)
10000 (16)
10001 (17)
10010 (18)
10011 (19)
10100 (20)
10101 (21)
10110 (22)
10111 (23)
11000 (24)
11001 (25)
11010 (26)
11011 (27)
11100 (28)
11101 (29)
11110 (30)
11111 (31)
Message Format
Receive
1
B.40.1.1.3
Reserved B.40.2.1 2
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
B.40.2.2.1 3
User Defined
User Defined
B.40.1.1.5.8 4
User Defined
User Defined
User Defined
User Defined
B.40.2.2.4 5
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
B.40.2.2.4
User Defined
User Defined
User Defined
B.40.1.1.3
Description
Transmit
B.40.1.1.3
Store Description
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
Reserved
User Defined
User Defined
B.40.2.2.1
User Defined
User Defined
B.40.1.5.8
User Defined
User Defined
User Defined
User Defined
B.40.2.2.5 6
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
User Defined
B.40.2.2.5
User Defined
User Defined
User Defined
B.40.1.1.3
Mode Code Indicator
Test Only
Mission Store Control/Monitor
Mass Data Transfer
Nuclear Weapon
Nuclear Weapon
Mode Code Indicator
Notes:
1. Refer to section B.40.1.1.3 of the MIL-STD-1760A specification for definition.
2. Refer to section B.40.2.1 of the MIL-STD-1760A specification for definition.
3. Refer to section B.40.2.2.1 of the MIL-STD-1760A specification for definition.
4. Refer to section B.40.1.1.5.8 of the MIL-STD-1760A specification for definition.
5. Refer to section B.40.2.2.4 of the MIL-STD-1760A specification for definition.
6. Refer to section B.40.2.2.5 of the MIL-STD-1760A specification for definition.
7. Reserved subaddresses illegalized; Message Error bit and pin set; SW transmitted.
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RTS-11
1.6 Terminal Address
The Terminal Address of the RTS is programmed via five
input pins: RTA(4:0) and RTPTY. Asserting MRST latches
the RTS’s Terminal Address from pins RTA(4:0) and parity
bit RTPTY. The address and parity cannot change until the
next assertion of the MRST. The parity of the Terminal
Address is odd; input pin RTPTY is set to a logic state to
satisfy this requirement. A logic 1 on Status Register
bit 12 indicates incorrect Terminal Address parity. An
example follows:
RTA(4:0) = 05 (hex) = 00101
RTPTY = 1 (hex) = 1
Sum of 1’s = 3 (odd), Status Register bit 12 = 0
RTA(4:0) = 04 (hex) = 00100
RTPTY = 0 (hex) = 0
Sum of 1’s = 1 (odd), Status Register bit 12 = 0
RTA(4:0) = 04 (hex) = 00100
RTPTY = 1 (hex) = 1
Sum of 1’s = 2 (even), Status Register bit 12 = 1
The RTS checks the Terminal Address and parity on Master
Reset. The state of the DSCNCT signal indicates the mated
status of the store. When all six Terminal Address pins
(RTA(4:0), RTPTY) go to a logic one, the DSCNCT pin is
asserted. To enable the disconnect function (DSCNCT pin)
bit 11 of the Control Register is set to a logic one. With
broadcast disabled, RTA (4:0) = 11111 operates as a normal
RT address.
1.7 Internal Self-Test
Setting bit 6 of the Control Register to a logic one enables
the internal self-test. Disable Channels A and B at this time
to prevent bus activity during self-test by setting bits 0 and
1 of the Control Register to a logic zero. Normal operation
is inhibited when internal self-test is enabled. The self-test
capability of the RTS is based on the fact that the MIL-STD1553B status word sync pulse is identical to the command
word sync pulse. Thus, if the status word from the encoder
is fed back to the decoder, the RTS will recognize the
incoming status word as a command word and thus cause
the RTS to transmit another status word. After the host
invokes self-test, the RTS self-test logic forces a status word
transmission even though the RTS has not received a valid
command. The status word is sent to decoder A or B
depending on the channel the host selected for self-test. The
self-test is controlled by the host periodically changing the
bit patterns in the status word being transmitted. Writing to
the Control Register bits 2, 3, 4, 7, 8, and 10 changes the
status word. Monitor the self-test by sampling either the
Status Register or the external status pins (i.e., Command
Strobe (COMSTR), Transmit/Receive (T/R)). For more
detailed explanation of internal self-test, consult UTMC
publication RTR/RTS Internal Self-Test Routine.
1.8 Power-up and Master Reset
After power-up, reset initializes the part with its biphase
ports enabled, latches the Terminal Address, selects Notice
III subaddress decoding, and turns on the busy option. The
device is ready to accept commands from the MIL-STD1553B bus. The busy flag is asserted while the host is loading
the message pointers and messages. After this task is
completed, the host removes the busy condition via a
Control Register write to the RTS. On power-up if the
terminal address parity (odd) is incorrect, the biphase inputs
are disabled and the message error pin (MERR) is asserted.
This condition can also be monitored via bit 12 of the Status
Register. The MERR pin is negated on reception of first
valid command.
1.9 Encoder and Decoder
The RTS interfaces directly to a bus transmitter/ receiver via
the RTS Manchester II encoder/decoder. The UT1760A
RTS receives the command word from the MIL-STD1553B bus and processes it either by the primary or
secondary decoder. Each decoder checks for the proper sync
pulse and Manchester waveform, edge skew, correct number
of bits, and parity. If the command is a receive command,
the RTS processes each incoming data word for correct
format and checks the control logic for correct word count
and contiguous data. If an invalid message error is detected,
the message error pin is asserted, the RTS ceases processing
the remainder (if any) of the message, and it then suppresses
status word transmission. Upon command validation
recognition, the external status outputs are enabled.
Reception of illegal commands does not suppress status
word transmission.
The RTS automatically compares the transmitted word
(encoder word) to the reflected decoder word by way of the
continuous loop-back feature. If the encoder word and
reflected word do not match, the transmitter error pin
(TXERR) is asserted. In addition to the loop-back compare
test, a timer precludes a transmission greater than 760µs by
the assertion of Fail-safe Timer (TIMERON). This timer is
reset upon receipt of another command. (RT-to-RT transfer
time-out = 57µs).
1.10 RT-RT Transfer Compare
The RT-to-RT Terminal Address compare logic makes sure
that the incoming status word’s Terminal Address matches
the Terminal Address of the transmitting RT specified in the
command word. An incorrect match results in setting the
message error bit and suppressing transmission of the
status word.
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RTS-12
1.11 Illegal Command Decoding
The host has the option of asserting the ILLCOM pin to
illegalize a received command word. On receipt of an illegal
command, the RTS sets the Message Error bit in the status
word, sets the message error output, and sets the message
error latch in the Status Register.
The following RTS outputs may be used to externally
decode an illegal command, Mode Code or Subaddress
indicator (MC/SA), Mode Code or Subaddress bus
MCSA(4:0), Command Strobe (COMSTR), Broadcast
(BRDCST), and Remote Terminal to Remote Terminal
transfer (RTRT) (see figure 21 on page 34.)
To illegalize a transmit command, the ILLCOM pin must
be asserted within 3.3µs after VALMSG goes to a logic 1 if
the RTS is to respond with the Message Error bit of the status
word at a logic 1. If the illegal command is mode code 2, 4,
5, 6, 7, or 18, the ILLCOM pin must be asserted within 664ns
after Command Strobe (COMSTR) transitions to logic 0.
Asserting the ILLCOM pin within the 664ns inhibits the
mode code function. For mode code illegalization, assert the
ILLCOM pin until the VALMSG signal is asserted.
For an illegal receive command, the ILLCOM pin must be
asserted within 18.2µs after the COMSTR transitions to a
logic 0 in order to suppress data words from being stored.
In addition, the ILLCOM pin must be at a logic 1 throughout
the reception of the message until VALMSG is asserted.
This does not apply to illegal transmit commands since the
status word is transmitted first.
The above timing conditions also apply when the host
externally decodes an illegal broadcast command. The host
must remove the illegal command condition so that the next
command is not falsely decoded as illegal.
2.0 MEMORY MAP EXAMPLE
Figures 5 and 6 illustrate the UT1760A RTS buffering three
receive command messages to Subaddress 4. The receive
message pointer for Subaddress 4 is located at 03C4 (hex)
in the 1K x 16 RAM. The 16-bit contents of location 03C4
(hex) point to the memory location where the first receive
message is stored. The Address Field defined as bits 0
through 9 of address 03C4 (hex) contain address
information. The Index Field defined as bits 10 through 15
of address 03C4 (hex) contain the message buffer index (i.e.,
number of messages buffered).
Figure 5 demonstrates the updating of the message pointer
as each message is received and stored. The memory storage
of these three messages is shown in figure 6. After receiving
the third message for Subaddress 4 (i.e., Index Field equals
zero) the Address Field of the message pointer is not
incremented. If the host does not update the receive
message pointer for Subaddress 4 before the next receive
command for Subaddress 4 is accepted, the third message
will be overwritten.
Figures 7 and 8 show an example of multiple message
retrieval from Subaddress 16 upon reception of a MIL-STD1553B transmit command. The message pointer for transmit
Subaddress 16 is located at 03F0 (hex) in the 1K x 16 RAM.
The 16-bit contents of location 03F0 (hex) point to the
memory location where the first message data words
are stored.
Figure 7 demonstrates the updating of the message pointer
as each message is received and stored. The data memory
for these three messages is shown in figure 8.
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RTS-13
Example:
Remote terminal will receive and buffer three MIL-STD-1553 receive commands
of various word lengths to Subaddress 4.
MIL-STD-1553 Bus Activity:
CMD WORD #1
DW0 DW1 DW2 DW3
SA = 4
T/R = 0
WC = 4
CMD WORD #2
SA = 4
T/R = 0
WC = 2
DW0 DW1
CMD WORD #3
DW0 DW1 DW2 DW3
SA = 4
T/R = 0
WC = 4
INDEX = 0000 10
0840 (hex)
ADDRESS = 00 0100 0000
Receive Subaddress 4;
data pointer at 03C4
(hex). (Initial condition)
03C4 (hex)
After message #1,
4 data words plus
command word.
03C4 (hex)
0445 (hex)
INDEX = 0000 01
ADDRESS = 00 0100 0101
After message #2,
2 data words plus
command word.
03C4 (hex)
0048 (hex)
INDEX = 0000 00
ADDRESS = 00 0100 1000
After message #3,
4 data words plus
command word.
03C4 (hex)
0048 (hex)
INDEX = 0000 00
ADDRESS = 00 0100 1000
Figure 5. RTS Message Handling
03C4 (hex)
03C4 (hex)
03C4 (hex)
03C4 (hex)
0840 (hex)
0445 (hex)
0048 (hex)
0048 (hex)
COMMAND WORD #1
041 (hex)
DATA WORD 1
042 (hex)
DATA WORD 2
043 (hex)
DATA WORD 3
044 (hex)
COMMAND WORD #2
045 (hex)
DATA WORD 0
046 (hex)
DATA WORD 1
047 (hex)
COMMAND WORD #3
048 (hex)
DATA WORD 0
049 (hex)
DATA WORD 1
04A (hex)
DATA WORD 2
04B (hex)
DATA WORD 3
04C (hex)
Figure 6. Memory Storage Subaddress 4
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RTS-14
040 (hex)
DATA WORD 0
Example:
Remote terminal will transmit and buffer three MIL-STD-1553 transmit commands
of various word lengths to Subaddress 16.
MIL-STD-1553 Bus Activity:
CMD WORD #1 SW DW0 DW1 DW2 DW3
SA = 16
CMD WORD #2 SW SW0 DW1
T/R = 1
WC = 4
SA = 16
CMD WORD #3 SW DW0 DW1 DW2 DW3
T/R = 1
WC = 2
SA = 16
T/R = 1
WC = 4
Transmit Subaddress 16;
data pointer at 03F0
(hex). (Initial condition)
03F0 (hex)
0830 (hex)
INDEX = 0000 10
ADDRESS = 00 0011 0000
After message #1,
4 data words.
03F0 (hex)
0434 (hex)
INDEX = 0000 01
ADDRESS = 00 0011 0100
After message #2,
2 data words.
03F0 (hex)
0036 (hex)
INDEX = 0000 00
ADDRESS = 00 0011 0110
After message #3,
4 data words.
03F0 (hex)
0036 (hex)
INDEX = 0000 00
ADDRESS = 00 0011 0110
Figure 7. RTS Message Handling
03F0(hex)
03F0 (hex)
03F0 (hex)
03F0 (hex)
0830 (hex)
0434 (hex)
0036 (hex)
0036(hex)
(hex)
034
DATA WORD 0
030 (hex)
DATA WORD 1
031 (hex)
DATA WORD 2
032 (hex)
DATA WORD 3
033 (hex)
DATA WORD 0
034 (hex)
DATA WORD 1
035 (hex)
DATA WORD 0
036 (hex)
DATA WORD 1
037 (hex)
DATA WORD 2
038 (hex)
DATA WORD 3
039 (hex)
Note:
Example is valid only if message structure is known in advance.
Figure 8. Memory Storage Subaddress 16
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RTS-15
3.0 PIN IDENTIFICATION AND DESCRIPTION
BIPHASE OUT
TAZ
TAO
A10
B10
TBZ
TBO
A9
B9
RAZ
RAO
RBZ
RBO
L7
K8
L6
K7
RTA0
RTA1
RTA2
RTA3
RTA4
RTPTY
L5
K5
L4
K4
L3
K6
MCSA0
MCSA1
MCSA2
MCSA3
MCSA4
B2
A2
A3
B3
A4
MERR
DSCNCT/TERACT
TXERR
TIMERON
COMSTR
MC/SA
BRDCST
T/R
RTRT
VALMSG
RBUSY
A5
A6
B5
B6
B8
B1
A7
B4
B7
L8
C2
BIPHASE IN
TERMINAL
ADDRESS
MODE/CODE
SUBADDRESS
STATUS
SIGNALS
CONTROL
SIGNALS
CS
RD/WR
CTRL
OE
ILLCOM
J2
H1
H2
G1
G2
F1
E2
D1
D2
C1
ADDR0
ADDR1
ADDR2
ADDR3
ADDR4
ADDR5
ADDR6
ADDR7
ADDR8
ADDR9
ADDRESS
BUS
ADDR(9:0)
L10
K10
DATA BUS
DATA(15:0)
C11
B11
DATA0
DATA1
DATA2
DATA3
DATA4
DATA5
DATA6
DATA7
DATA8
DATA9
DATA10
DATA11
DATA12
DATA13
DATA14
DATA15
F10
VDD
E1
VDD
POWER
F2
G11
VSS
VSS
GROUND
12MHZ
2MHZ
CLOCK
A8
K3
MRST
RESET
K11
J10
J11
UT1760A
RTS
K2
K1
J1
L9
K9
H10
H11
G10
F11
E10
E11
D10
D11
C10
L2
Figure 9. UT1760A RTS Pin Description
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RTS-16
Legend for TYPE and ACTIVE Fields:
TTO = Three-state TTL output
TTB = Three-state TTL bidirectional
AL = Active low
AH = Active high
[] - Value in parentheses indicates initial state of
these pins.
TI = TTL input
TUI = TTL input (pull-up)
TDI = TTL input (pull-down)
TO = TTL output
DATA BUS
NAME
DATA15
PIN NUMBER
(PGA)
B11
DATA14
DATA13
DATA12
DATA11
DATA10
DATA9
DATA8
DATA7
DATA6
DATA5
DATA4
DATA3
DATA2
DATA1
DATA0
C11
C10
D11
D10
E11
E10
F11
G10
H11
H10
J11
J10
K11
K10
L10
TYPE
ACTIVE
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
TTB
-----------------
TYPE
ACTIVE
TI
TI
TI
TI
TI
TI
TI
TI
TI
TI
-----------
DESCRIPTION
Bit 15 (MSB) of the bidirectional Data bus.
Bit 14 of the bidirectional Data bus.
Bit 13 of the bidirectional Data bus.
Bit 12 of the bidirectional Data bus.
Bit 11 of the bidirectional Data bus.
Bit 10 of the bidirectional Data bus.
Bit 9 of the bidirectional Data bus.
Bit 8 of the bidirectional Data bus.
Bit 7 of the bidirectional Data bus.
Bit 6 of the bidirectional Data bus.
Bit 5 of the bidirectional Data bus.
Bit 4 of the bidirectional Data bus.
Bit 3 of the bidirectional Data bus.
Bit 2 of the bidirectional Data bus.
Bit 1 of the bidirectional Data bus.
Bit 0 (LSB) of the bidirectional Data bus.
ADDRESS BUS
NAME
ADDR9
PIN NUMBER
(PGA)
C1
ADDR8
ADDR7
ADDR6
ADDR5
ADDR4
ADDR3
ADDR2
ADDR1
ADDR0
D2
D1
E2
F1
G2
G1
H2
H1
J2
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DESCRIPTION
Bit 9 (MSB) of the Address bus.
Bit 8 of the Address bus.
Bit 7 of the Address bus.
Bit 6 of the Address bus.
Bit 5 of the Address bus.
Bit 4 of the Address bus.
Bit 3 of the Address bus.
Bit 2 of the Address bus.
Bit 1 of the Address bus.
Bit 0 (LSB) of the Address bus.
RTS-17
CONTROL INPUTS
NAME
PIN NUMBER
(PGA)
K2
TYPE
ACTIVE
DESCRIPTION
TI
AL
RD/WR
K1
TI
--
CTRL
J1
TI
AL
OE
L9
TI
AL
Chip Select. The host processor uses the CS signal for
RTS Status Register reads, Control Register writes, or
host access to the RTS internal RAM.
Read/Write. The host processor uses a high level on this
input in conjunction with CS to read the RTS Status
Register or the RTS internal RAM. A low level on this
input is used in conjunction with CS to write to the RTS
Control Register or the RTS internal RAM.
Control. The host processor uses the active low CTRL
input signal in conjunction with CS and
RD/WR to access the RTS registers. A high level on this
input means access is to RTS internal RAM only.
Output Enable. The active low OE signal is used to
control the direction of data flow from the RTS.
For OE = 1, the RTS Data bus is three-state; for
OE = 0, the RTS Data bus is active.
ILLCOM
K9
TDI
AH
CS
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RTS-18
Illegal Command. The host processor uses the
ILLCOM input to inform the RTS that the present
command is illegal.
STATUS OUTPUTS
NAME
PIN NUMBER
(PGA)
A5
TYPE
ACTIVE
DESCRIPTION
TO
AH
TXERR
[0]
B5
TO
AH
TIMERON
[1]
B6
TO
AL
COMSTR
[1]
B8
TO
AL
BRDCST
[1]
A7
TO
AL
RTRT
[0]
B7
TO
AH
DSCNCT or
TERACT
[X]
A6
TO
--
VALMSG
[0]
L8
TO
AH
RBUSY
[0]
C2
TO
AH
T/R
[0]
B4
TO
--
Message Error. The active high MERR output signals that
the Message Error bit in the Status Register has been set
due to receipt of an illegal command, or an error during
message sequence. MERR will reset to logic zero on the
receipt of the next valid command.
Transmission Error. The active high TXERR output is
asserted when the RTS detects an error in the reflected
word versus the transmitted word, using the continuous
loop-back compare feature. Reset on next COMSTR
assertion.
Fail-safe Timer. The TIMERON output pulses low for
760µs when the RTS begins transmitting (i.e., rising edge
of VALMSG) to provide a fail-safe timer meeting the
requirements of MIL-STD-1553B. This pulse is reset
when COMSTR goes low or during a Master Reset.
Command Strobe. COMSTR is an active low output of
500ns duration identifying receipt of a valid command.
Broadcast. BRDCST is an active low output that identifies
receipt of a valid broadcast command.
Remote Terminal to Remote Terminal. RTRT is an active
high output indicating that the RTS is processing a remote
terminal to remote terminal command.
Disconnect or Terminal Active. Bit 11 of the Control
Register selects the mode of this dual-function pin. In the
“Disconnect” mode (bit 11 = 1), the active high DSCNCT
output is asserted when all six Terminal Address pins
(RTA0 - RTA4, RTPTY) go high, indicating a disconnect
condition. In the “Terminal Active” mode (bit 11 = 0), the
active low TERACT output is asserted at the beginning of
the RTS access to internal RAM for a given command and
negated after the last access for that command.
Valid Message. VALMSG is an active high output
indicating a valid message (including Broadcast) has
been received. VALMSG goes high prior to transmitting
the 1553 status word and is reset upon receipt of the
next command.
RTS Busy. RBUSY is asserted high while the RTS is
accessing its own internal RAM either to read or update
the pointers or to store or retrieve data words. RBUSY
becomes active either 2.7µs or 5.7µs before RTS requires
RAM access. This timing is controlled by Control Register
bit 12 (see section 1.3).
Transmit/Receive. A high level on this pin indicates a
transmit command message transfer is being or was
processed, while a low level indicates a receive command
message transfer is being or was processed.
MERR
[0]
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RTS-19
MODE CODE/SUBADDRESS OUTPUTS
NAME
PIN NUMBER
(PGA)
B1
TYPE
ACTIVE
DESCRIPTION
TO
--
MCSA0
[0]
B2
TO
--
MCSA1
[0]
MCSA2
[0]
MCSA3
[0]
MCSA4
[0]
A2
TO
--
Mode Code/Subaddress Indicator. If MC/SA is low, it indicates that the most recent command word is a mode code
command. If MC/SA is high, it indicates that the most
recent command word is for a subaddress. This output
indicates whether the mode code/subaddress ouputs (i.e.,
MCSA(4:0)) contain mode code or subaddress information.
Mode Code/Subaddress Output 0. If MC/SA is low, this pin
represents the least significant bit of the most recent
command word (the LSB of the mode code). If MC/SA is
high, this pin represents the LSB of the subaddress.
Mode Code/Subaddress Output 1.
A3
TO
--
Mode Code/Subaddress Output 2.
B3
TO
--
Mode Code/Subaddress Output 3.
A4
TO
--
Mode Code/Subaddress Output 4. If MC/SA is low, this pin
represents the most significant bit of the mode code. If MC/
SA is high, this pin represents the MSB of the subaddress.
MC/SA
[0]
REMOTE TERMINAL ADDRESS INPUTS
NAME
RTA4
RTA3
RTA2
RTA1
RTA0
RTPTY
PIN NUMBER
(PGA)
L3
K4
L4
K5
L5
K6
TYPE
ACTIVE
DESCRIPTION
TUI
TUI
TUI
TUI
TUI
TUI
-------
Remote Terminal Address bit 4 (MSB).
Remote Terminal Address bit 3.
Remote Terminal Address bit 2.
Remote Terminal Address bit 1.
Remote Terminal Address bit 0 (LSB).
Remote Terminal Address Parity. This input must provide
odd parity for the Remote Terminal Address.
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RTS-20
BIPHASE INPUTS 1
NAME
TYPE
ACTIVE
RAZ
PIN NUMBER
(PGA)
L7
TI
--
RAO
K8
TI
--
RBZ
L6
TI
--
RBO
K7
TI
--
DESCRIPTION
Receiver - Channel A, Zero Input. Idle low Manchester
input form the 1553 bus receiver.
Receiver - Channel A, One Input. This input is the
complement of RAZ.
Receiver - Channel B, Zero Input. Idle low Manchester
input from the 1553 bus receiver.
Receiver - Channel B, One Input. This input is the
complement of RBZ.
Note:
1. For uniphase operation, tie RAZ (or RBZ) to VDD and apply true uniphase input signal to RAO (or RBO).
BIPHASE OUTPUTS
NAME
PIN NUMBER
(PGA)
A10
TYPE
ACTIVE
DESCRIPTION
TO
--
TAO
[0]
B10
TO
--
TBZ
[0]
A9
TO
--
Transmitter - Channel A, Zero Output. This Manchester
encoded data output is connected to the 1553 bus
transmitter input. The output is idle low.
Transmitter - Channel A, One Output. This output is the
complement of TAZ. The output is idle low.
Transmitter - Channel B, Zero Output. This Manchester
encoded data output is connected to the 1553 bus
transmitter input. The output is idle low.
TBO
[0]
B9
TO
--
Transmitter - Channel B, One Output. This output is the
complement of TBZ. The output is idle low.
TYPE
ACTIVE
DESCRIPTION
MRST
PIN NUMBER
(PGA)
K3
TUI
AL
12MHz
L2
TI
--
2MHz
A8
TO
--
Master Reset. Initializes all internal functions of the RTS.
MRST must be asserted 500ns before normal RTS
operation (500ns minimum). Does not reset RAM.
12 MHz Input Clock. This is the RTS system clock that
requires an accuracy greater than 0.01% with a duty cycle
of 50% ± 10%.
2MHz Clock Output. This is a 2MHz clock output
generated by the 12MHz input clock. This clock is
stopped when MRST is low.
TAZ
[0]
MASTER RESET AND CLOCK
NAME
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RTS-21
POWER AND GROUND
NAME
VDD
VSS
PIN NUMBER
(PGA)
F10
E1
F2
G11
TYPE
ACTIVE
PWR
PWR
GND
GND
-----
DESCRIPTION
+5 VDC Power. Power supply must be +5 VDC
± 10%.
Reference ground. Zero VDC logic ground.
4.0 OPERATING CONDITIONS
ABSOLUTE MAXIMUM RATINGS*
(referenced to VSS)
SYMBOL
VDD
PARAMETER
DC supply voltage
Voltage on any pin
DC input current
Storage temperature
Maximum power dissipation 1
Maximum junction temperature
Thermal resistance, junction-to-case
LIMITS
-0.3 to +7.0
-0.3 to VDD+0.3
±10
-65 to +150
300
+175
20
UNIT
V
LIMITS
4.5 to 5.5
0 to VDD
-55 to +125
12 ±.01%
UNIT
V
VIO
II
TSTG
PD
TJ
ΘJC
Note:
1. Does not reflect the added PD due to an output short-circuited.
* Stresses outsidethelistedabsolutemaximumratingsmay cause permanent damage to the device.Thisisa stressrating only,
and functional operation of the device at these or any other conditions beyond limits indicated in the operational
sections of this specification is not recommended. Exposure to absolute maximum rating conditions for extended
periods may affect device reliability.
V
mA
°C
mW
°C
°C/W
RECOMMENDED OPERATING CONDITIONS
SYMBOL
VDD
VIN
TC
FO
PARAMETER
DC supply voltage
DC input voltage
Temperature range
Operating frequency
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RTS-22
V
°C
MHz
5.0 DC ELECTRICAL CHARACTERISTICS
VDD = 5.0V ± 10%; -55°C < TC <+125°C)
SYMBOL
VIL
VIH
IIN
VOL
VOH
IOZ
IOS
PARAMETER
Low-level input voltage
High-level input voltage
Input leakage current
TTL inputs
Inputs with pull-down resistors
Inputs with pull-up resistors
Low-level output voltage
High-level output voltage
Three-state output
leakage current
Short-circuit output current 1, 2
CONDITION
MINIMUM
MAXIMUM
0.8
UNIT
V
2.0
VIN = VDD or VSS
VIN = VDD
VIN = VSS
IOL = 3.2µA
IOH = -400µA
VO = VDD or VSS
V
-1
110
-2000
2.4
-10
VDD = 5.5V, VO = VDD
µA
µA
µA
V
V
µA
1
2000
-110
0.4
+10
90
mA
mA
-90
VDD = 5.5V, VO = 0V
CIN
Input capacitance 3
ƒ = 1MHz @ 0V
10
pF
COUT
Output capacitance 3
ƒ = 1MHz @ 0V
15
pF
CIO
Bidirect I/O capacitance 3
ƒ = 1MHz @ 0V
20
pF
IDD
Average operating current 1, 4
ƒ = 12MHz, CL = 50pF
50
mA
QIDD
Quiescent current
Note 5
1.5
mA
Notes:
1. Supplied as a design limit but not guaranteed or tested.
2. Not more than one output may be shorted at a time for a maximum duration of one second.
3. Measured only for initial qualification, and after process or design changes that could affect input/output capacitance.
4. Includes current through input pull-ups. Instantaneous surge currents on the order of 1 ampere can occur during output switching.
Voltage supply should be adequately sized and decoupled to handle a large surge current.
5. All inputs with internal pull-ups or pull-downs should be left open circuit. All other inputs tied high or low.
10 11 12 13 14
5
1
5
1
5
P
1
1
RESERVED
Figure 10. MIL-STD-1553B Word Formats
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1
1
1
1
1
1
PARITY
1
TERMINAL FLAG
DATA
SERVICE REQUEST
ADDRESS
1
INSTRUMENTATION
5
REMOTE TERMINAL
P
16
MESSAGE ERROR
SYNC
SYNC
20
REMOTE TERMINAL T/R SUBADDRESS/MODE DATA WORD COUNT/
MODE CODE
ADDRESS
CODE
DATA WORD
STATUS WORD
15 16 17 18 19
DYNAMIC BUS CONTROL ACCEPTANCE
SYNC
9
SUBSYSTEM FLAG
COMMAND
WORD
45678
BUSY
123
BROADCAST COMMAND RECEIVED
BIT TIMES
RTS-23
6.0 AC ELECTRICAL CHARACTERISTICS
(Over recommended operating conditions)
VIH MIN
1
INPUT V MAX
IL
ta
IN-PHASE
2
OUTPUT
OUT-OF-PHASE
OUTPUT
tc
VIH MIN
VIL MAX
1
tb
2
VOH MIN
VOL MAX
VOH MIN
VOL MAX
td
2
2
te
VOH MIN
VOL MAX
BUS
tf
tg
th
SYMBOL
INPUT↑
INPUT↓
INPUT↑
INPUT↓
INPUT↓
INPUT↓
INPUT↑
INPUT↑
ta
tb
tc
td
te
tf
tg
th
PARAMETER
to response ↑
to response ↓
to response ↓
to response ↑
to data valid
to high Z
to high Z
to data valid
Notes:
1. Timing measurements made at (VIH MIN + VIL MAX)/2.
2. Timing measurements made at (VOL MAX + VOH MIN)/2.
3. Based on 50pf load.
4. Unless otherwise noted, all AC electrical characteristics are guaranteed by design or characterization.
Figure 11a. Typical Timing Measurements
5V
IREF (source)
3V
90%
90%
VREF
D
10%
10%
50pF
0V
IREF (sink)
< 2ns
< 2ns
Input Pulses
Note:
50pF including scope probe and test socket
Figure 11b. AC Test Loads and Input Waveforms
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RTS-24
12MHz
t12i
CS
t12j
t12a
t12f
CTRL
t12b
RD/WR
t12k
t12g
t12c
ADDR(9:0)
t12d
DATA(15:0)
t12l
DATA VALID
t1h
t12e
t12m
OE
Figure 12. Microprocessor RAM Read
SYMBOL
PARAMETER
MIN
MAX
UNITS
10
-ns
t12a
CTRL↑ set up wrt CS↓ 1
10
-ns
t12b
RD/WR ↑ set up wrt CS↓
10
-ns
t12c
ADDR(9:0) Valid to CS↓ (Address Set up)
-155
ns
t12d
CS↓ to DATA(15:0) Valid
-65
ns
t12e
OE↓ to DATA(15:0) Don’t Care (Active)
0
-ns
t12f
CS↑ to CTRL Don’t Care
0
-ns
t12g
CS↑ to ADDR(9:0) Don’t Care
-40
ns
t12h
OE↑ to DATA(15:0) High Impedance
220
5500
ns
t12i
CS↓ to CS↑ 2
85
-ns
t12j
CS↑ to CS↓
0
-ns
t12k
CS↑ to RD/WR Don’t Care
25
-ns
t12l
CS↑ to DATA(15:0) Invalid 3
65
-ns
t12m
OE↓ to OE↑
Notes:
1. “wrt” defined as “with respect to.”
2. The maximum amount of time that CS can be held low is 5500ns if the user has selected the 5.7µs RBUSY option. For the 2.7µs
RBUSY option, the maximum CS low time is 2500ns.
3. Assumes OE is asserted.
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RTS-25
12MHz
t13i
CS
t13j
t13a
t13k
CTRL
t13b
RD/WR
t13f
t13c
ADDR(9:0)
t13g
t13d
VALID DATA
DATA(15:0)
t13h
OE
t13e
Figure 13. Microprocessor RAM Write
SYMBOL
t13a
t13b
t13c
t13d
t13e
t13f
t13g
t13h
t13i
t13j
t13k
PARAMETER
CTRL↑ set up wrt CS↓
RD/WR ↑ set up wrt CS↓
ADDR(9:0) Valid to CS↓ (Address set up)
CS↓ to DATA(15:0) Valid CS↓(DATA set up)
OE↓ to DATA(15:0) High Impedance
CS↑ to RD/WR Don’t Care
CS↑ to ADDR(9:0) Don’t Care
CS↑ to DATA(15:0) Don’t Care (Hold-time)
CS↓ to CS↑ 1
CS↑ to CS↓
CS↑ to CTRL Don’t Care
MIN
MAX
UNITS
10
10
10
0
40
0
0
20
180
85
0
--------5500
---
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note:
1. The maximum amount of time that CS can be held low is 5500ns if the user has selected the 5.7µs RBUSY option. For the 2.7µs
RBUSY option, the maximum CS low time is 2500ns.
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RTS-26
12MHz
t14c
CS
t14a
t14e
CTRL
t14b
RD/WR
t14f
DATA(15:0)
t14h
VALID DATA
t14d
OE
t14g
Figure 14. Control Register Write
SYMBOL
t14a
t14b
t14c
t14d
t14e
t14f
t14g
t14h
PARAMETER
CTRL↓ set up wrt CS↓
RD/WR ↓ set up wrt CS↓
CS↓ to CS↑ 1
CS↑ to DATA(15:0) Don’t Care (Hold-time)
CS↑ to CTRL Don’t Care
CS↑ to RD/WR Don’t Care
OE↑ to Data(15:0) High Impedance
DATA (15:0) Valid to CS↓ (DATA set up)
MIN
MAX
UNITS
0
0
50
0
0
0
40
0
--5500
------
ns
ns
ns
ns
ns
ns
ns
ns
Note:
1. The maximum amount of time that CS can be held low is 5500ns if the user has selected the 5.7µs RBUSY option. For the 2.7µs
RBUSY option, the maximum CS low time is 2500ns.
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RTS-27
12MHz
t15b
CS
t15a
t15e
CTRL
t15c
RD/WR
t15f
t15d
t15j
VALID DATA
DATA(15:0)
t15g
t15h
t15i
OE
Figure 15. Status Register Read
SYMBOL
t15a
t15b
t15c
t15d
t15e
t15f
t15g
t15h
t15i
t15j
PARAMETER
MIN
MAX
UNITS
CTRL↓ set up wrt CS↓
CS↓ to CS↑1
RD/WR↑ set up wrt CS↓
CS↓ to DATA(15:0) Valid
CS↑ to CTRL Don’t Care
CS↑ to RD/WR Don’t Care
OE↓ to DATA(15:0) Don’t Care (Active)
OE↑ to DATA(15:0) High Impedance
OE↓ to OE↑
CS↓ to DATA(15:0) Don’t Care (Active)
0
65
0
-5
5
--65
25
-5500
-65
--65
40
---
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Note:
1. The maximum amount of time that CS can be held low is 5500ns if the user has selected the 5.7µs RBUSY option. For the 2.7µs RBUSY
option, the maximum CS low time is 2500ns.
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RTS-28
VALMSG
t16a
t16c
TIMERON
A/B
BIPHASE
OUTPUT ZERO
t16b
COMSTR
t16d
ILLCOM
t16g
t16f
t16e
Figure 16. RT Fail-Safe Timer Signal Relationships
SYMBOL
PARAMETER
t16a
VALMSG↑ before TIMERON↓
t16b
TIMERON↓ before first BIPHASE OUT O↑
t16c
TIMERON low pulse width (time-out)
t16d
COMSTR↓ to TIMERON↑
t16e
VALMSG↑ to ILLCOM↑
t16f
COMSTR↓ to ILLCOM↑ 1
t16f
COMSTR↓ to ILLCOM↑ 2
t16g
ILLCOM↑ to ILLCOM↓ 3
Notes:
1. Mode code 2, 4, 5, 6, 7, or 18 received.
2. To suppress data word storage.
3. For transmit command illegalization.
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MIN
MAX
UNITS
0
1.2
727.3
----500
35
-727.4
25
3.3
664
18.2
--
ns
µs
µs
ns
µs
ns
µs
ns
RTS-29
12MHz
CS
COMMAND WORD
P
1
BIPHASE IN
t17a
MC/SA
and MCSA(4:0)
t17b
t17c
COMSTR
t17l
t17d
t17e
BRDCST
t17f
t17g
T/R
t17h
t17i
VALMSG
t17j
t17k
MERR
Note:
1. Measured from the mid-bit parity crossing.
Figure 17. Status Output Timing
SYMBOL
PARAMETER
t17a 4
12Mhz↑ to MC/SA Valid
t17b
Command Word to MC/SA Valid3
4
t17c
12MHz↑ to COMSTR↓
t17d
Command Word to COMSTR↓3
4
t17e
12MHz↑ to BRDCST↓
t17f
Command Word to BRDCST↓3
4
t17g
12MHz↑ to T/R Valid
t17h
Command Word toT/R Valid3
4
t17i
12MHz↑ to VALMSG↑
t17j
Command Word toVALMSG↑ 1,2,3
4
t17k
12MHz↑ to MERR↑
t17l
COMSTR↓ TO COMSTR↑
Notes:
1. Receive last data word to Valid Message active (VALMSG↑).
2. Transmit command word to Valid Message active (VALMSG↑).
3. Command word measured from mid-bit crossing.
4. Guaranteed by test.
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RTS-30
MIN
MAX
UNITS
0
2.1
0
3.2
0
2.6
0
2.2
0
6.2
0
485
14
2.8
17
3.7
32
3.2
57
2.7
32
6.7
37
500
ns
µs
ns
µs
ns
µs
ns
µs
ns
µs
ns
ns
12MHz
CS
COMMAND WORD
P
t18a
BIPHASE IN
t18i
RBUSY
t18b
t18c
t18h
TERACT
t18d
t18e
RTRT
t18f
t18g
MRST
Note:
1. Measured from mid-bit parity crossing.
Figure 18. Status Output Timing
SYMBOL
PARAMETER
t18a
t18b
t18c2
t18d
t18e 2
t18f
t18g
12MHz↑ to RBUSY↑
Command Word toRBUSY↑ 3
12MHz↑ to TERACT↓
Command Word to TERACT↓ 1,3
12MHz↑ to RTRT↑
Command Word to RTRT↑ 3
MRST↓ to MRST↑
t18h
RBUSY↑ to RBUSY↓ (2.7µs)
(5.7µs)
t18i
RBUSY↓ to RBUSY↑ (2.7µs)
(5.7µs)
MIN
MAX
UNITS
-3.2
0
3.1
0
21.0
500
--3.10
240
37
3.8
37
3.7
32
22
-5.5
8.5
---
ns
µs
ns
µs
ns
µs
ns
µs
µs
µs
ns
Notes:
1. TERACT enabled via Control Register.
2. Guaranteed by test.
3. Command word measured from mid-bit crossing
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RTS-31
BIPHASE IN
CS COMMAND WORD DS DATA WORD P DS DATA WORD P
COMSTR
T/R
RBUSY
1
2
3
TERACT
SS
BIPHASE OUT
STATUS WORD P
VALMSG
Notes:
1. Burst of 5 DMAs: read command pointer, store command word, update command pointer, read data word pointer, store
command word.
2. Burst of 1 DMA: store data word.
3. Burst of 2 DMAs: store data word, update data word pointer.
4. Approximately 560ns per DMA access.
Figure 19a. Receive Command with Two Data Words
BIPHASE IN
CS
COMMAND WORD
P
COMSTR
T/R
RBUSY
1
2
3
TERACT
BIPHASE OUT
SS STATUS WORD
P
DS DATA WORD
P
DS DATA WORD
VALMSG
CS = Command sync
SS = Status sync
DS = Data sync
P = Parity
Notes:
1. Burst of 4 DMAs: read command pointer, store command word, update command pointer, read data word pointer.
2. Burst of 1 DMA: read data word.
3. Burst of 2 DMAs: read data word, update data word pointer.
4. Approximately 560ns per DMA access.
Figure 19b. Transmit Command with Two Data Words
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RTS-32
P
ADDR(9:0)
DATA(15:0)
HOST
SUBSYSTEM
UT1760A
RTS
CONTROL
UT63M125
1553 TRANSCEIVER
1553 BUS A
1553 BUS B
Figure 20a. RTS General System Diagram (Idle low interface)
RAO
RAZ
RXOUT
RXOUT
CHANNEL A
TXINHB
CHANNEL A
TXIN
TXIN
TAO
TAZ
UTMC
63M125
RTS
RBO
RBZ
RXOUT
RXOUT
TXINHB
CHANNEL B
TBO
TBZ
CHANNEL B
TXIN
TXIN
TIMERON
Figure 20b. RTS Transceiver Interface Diagram
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RTS-33
MC/SA
MCSA0
MCSA1
ILLEGAL
COMMAND
DECODER
MCSA2
MCSA3
RTS
MCSA4
COMSTR
BRDCST
T/R
RTRT
ILLCOM
Figure 21. Mode Code/Subaddress Illegalization Circuit
7.0 PACKAGE OUTLINE DRAWING
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RTS-34
L
L2
L3
L4
L5
L6
L7
L8
L9
L10
K3
K4
K5
K6
K7
K8
K9
K10
K11
K
K1
K2
J
J1
J2
J10
J11
H
H1
H2
H10
H11
G
G1
G2
G10
G11
F
F1
F2
F10
F11
E
E1
E2
E10
E11
D
D1
D2
D10
D11
C
C1
C2
C10
C11
B
B1
B2
B3
B4
B5
B6
B7
B8
B9
B10
B11
A2
A3
A4
A5
A6
A7
A8
A9
A10
2
3
4
5
6
7
8
9
10
A
1
A2
A3
A4
A5
A6
MCSA1
MCSA2
MCSA4
MERR
TERACT or
DSCNCT
A7 BRDCST
A8 2MHz
A9 TBZ
A10 TAZ
B1
B2
B3
B4
B5
B6
B7
B8
MC/SA
MCSA0
MCSA3
T/R
TXERR
TIMERON
RTRT
COMSTR
C1
C2
C10
C11
ADDR9
RBUSY
DATA13
DATA14
G1
G2
G10
G11
ADDR3
ADDR4
DATA7
VSS
D1
D2
D10
D11
ADDR7
ADDR8
DATA11
DATA12
H1
H2
H10
H11
ADDR1
ADDR2
DATA5
DATA6
E1
E2
E10
E11
VDD
ADDR6
DATA9
DATA10
J1
J2
CTRL
ADDR0
F1
ADDR5
K1
K2
K3
K4
K5
K6
K7
K8
K9
K10
K11
L2
L3
L4
L5
L6
L7
L8
11
RD/WR
CS
MRST
RTA3
RTA1
RTPTY
RBO
RAO
ILLCOM
DATA1
DATA2
12MHz
RTA4
RTA2
RTA0
RBZ
RAZ
VALMSG
Figure 22. UT1760A RTS Pingrid Array Configuration (Bottom View)
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RTS-35
Package Selection Guide
RTI
24-pin DIP
(single cavity)
36-pin DIP
(dual cavity)
68-pin PGA
84-pin PGA
144-pin PGA
84-lead LCC
36-lead FP
(dual cavity)
(50-mil ctr)
84-lead FP
132-lead FP
RTMP
RTR
Product
BCRT BCRTM BCRTMP
RTS
XCVR
X
X
X
X
X
X
X
X1
X
X1
X
X
X
X
X
X
X
NOTE:
1. 84LCC package is not available radiation-hardened.
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Packaging-1
D
1.565 ± 0.025
A
0.130 MAX.
-A-
Q
0.050 ± 0.010
0.040 REF.
0.080 REF.
(2 Places)
A
L
0.130 ±0.010
0.100 REF.
(4 Places)
E
1.565 ± 0.025
-B-
PIN 1 I.D.
(Geometry Optional)
e
0.100
TYP.
TOP VIEW
-CA
(Base Plane)
b
0.018 ± 0.002
0.030 C A B
0.010 C 2
R
SIDE VIEW
P
N
M
L
K
J
D1/E1
1.400
H
G
F
E
D
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
PIN 1 I.D.
(Geometry Optional)
BOTTOM VIEW
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0.003 MIN. TYP.
Notes:
1. True position applies to pins at base plane (datum C).
2. True position applies at pin tips.
3. All package finishes are per MIL-M-38510.
4. Letter designations are for cross-reference to MIL-M-38510.
144-Pin Pingrid Array
Packaging-2
1
D/E
1.525 ± 0.015 SQ.
D1/E1
0.950 ± 0.015 SQ.
A
0.110
0.006
A
PIN 1 I.D.
(Geometry
Optional)
e
0.025
SEE DETAIL A
A
LEAD KOVAR
TOP VIEW
C
0.005 + 0.002
- 0.001
L
0.250
MIN.
REF.
S1
0.005 MIN. TYP.
SIDE VIEW
0.018 MAX. REF.
0.014 MAX. REF.
(At Braze Pads)
DETAIL A
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BOTTOM VIEW A-A
Notes:
1. All package finishes are per MIL-M-38510.
2. Letter designations are for cross-reference to MIL-M-38510.
132-Lead Flatpack (25-MIL Lead Spacing)
Packaging-3
A
0.115 MAX.
D/E
1.150 ± 0.015 SQ.
A1
0.080 ± 0.008
A
PIN 1 I.D.
(Geometry Optional)
TOP VIEW
SIDE VIEW
L/L1
0.050 ± 0.005 TYP.
h
0.040 x 45_
REF. (3 Places)
B1
0.025 ± 0.003
e
0.050
J
0.020 X 455 REF.
e1
0.015 MIN.
PIN 1 I.D.
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2003
(Geometry
Optional)
BOTTOM VIEW A-A
Notes:
1. All package finishes are per MIL-M-38510.
2. Letter designations are for cross-reference to MIL-M-38510.
84-LCC
Packaging-4
A
D/E
1.810 ± 0.015 SQ.
D1/E1
1.150 ± 0.012 SQ.
A
0.110
0.060
PIN 1 I.D.
(Geometry
Optional)
A
e
0.050
b
0.016 ± 0.002
SEE DETAIL A
A
LEAD KOVAR
C
0.007 ± 0.001
TOP VIEW
L
0.260
MIN.
REF.
S1
0.005 MIN. TYP.
SIDE VIEW
0.018 MAX. REF.
0.014 MAX.
REF.
(At Braze Pads)
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BOTTOM2003
VIEW
A-A
DETAIL A
Notes:
1. All package finishes are per MIL-M-38510.
2. Letter designations are for cross-reference to MIL-M-38510.
84-Lead Flatpack (50-MIL Lead Spacing)
Packaging-5
D
1.100 ± 0.020
A
0.130 MAX.
-A-
Q
0.050 ± 0.010
A
L
0.130 ± 0.010
E
1.100 ± 0.020
PIN 1 I.D.
(Geometry Optional)
-B-
-C(Base Plane)
TOP VIEW
e
0.100
TYP.
0.030 C A B
0.010 C 2
SIDE VIEW
L
K
J
H
G
D1/
1.000
F
E
D
1
A
b
0.018 ± 0.002
2
3
4
5
6
7
8 9 10 11
PIN 1 I.D.
(Geometry Optional)
BOTTOM VIEW A-A
0.003 MIN.
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Notes: Service CopyRight 2003
1.
2.
3.
4.
True position applies to pins at base plane (datum C).
True position applies at pin tips.
All packages finishes are per MIL-M-38510.
Letter designations are for cross-reference to MIL-M-38510.
84-Pin Pingrid Array
Packaging-6
1
D
1.100 ± 0.020
A
0.130 MAX.
Q
0.050 ± 0.010
-A-
A
L
0.130 ± 0.010
E
1.100 ± 0.020
-B-
PIN 1 I.D.
(Geometry Optional)
A
-C(Base Plane)
TOP
b
0.010 ± 0.002
∅ 0.030 C A B
∅ 0.010 C 2
e
0.100
TYP.
1
SIDE VIEW
L
K
J
H
G
F
E
D
C
B
A
D1/E1
1.00
1 2 3 4 5 6
PIN 1 I.D.
(Geometry Optional)
7
8
9
10 11
0.003 MIN. TYP.
BOTTOM VIEW A-A
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Notes:
1 True position applies to pins at base plane (datum C).
2 True position applies at pin tips.
3. All packages finishes are per MIL-M-38510.
4. Letter designations are for cross-reference to MIL-M-38510.
68-Pin Pingrid Array
Packaging-7
E
0.750 ± 0.015
L
0.490
MIN.
b
0.015 ± 0.002
D
1.800 ± 0.025
e
0.10
PIN 1 I.D.
(Geometry Optional)
TOP VIEW
c
0.008
+ 0.002
- 0.001
A
0.130 MAX.
END VIEW
Notes:
1 All package
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2003
finishes are per MIL-M-38510.
2. It is recommended that package ceramic be mounted to
a heat removal rail located on the printed circuit board.
A thermally conductive material such as MERECO XLN-589 or
equivalent should be used.
3. Letter designations are for cross-reference to MIL-M-38510.
36-Lead Flatpack, Dual Cavity (100-MIL Lead Spacing)
Packaging-8
Q
0.080 ± 0.010
(At Ceramic Body)
E
0.700 + 0.015
L
0.330
MIN.
b
0.016 + 0.002
D
1.000 ± 0.025
e
0.050
PIN 1 I.D
(Geometry Optional)
TOP
+ 0.002
c
0.007 - 0.001
A
0.100 MAX.
END
Q
0.070 + 0.010
(At Ceramic Body)
Notes:
1. All package finishes are per MIL-M-38510.
2. It is recommended that package ceramic be mounted to
a heat removal rail located on the printed circuit board.
A thermally conductive material such as MERECO XLN-589
or equivalent should be used.
3. Letter designations are for cross-reference to MIL-M-38510.
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36-Lead Flatpack, Dual Cavity (50-MIL Lead Spacing)
Packaging-9
E
0.590 ± 0.012
S1
0.005 MIN.
S2
0.005 MAX.
e
0.100
D
1.800 ± 0.025
b
0.018 ± 0.002
PIN 1 I.D.
(Geometry Optional)
A
0.155 MAX.
TOP VIEW
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C
0.010 +- 0.002
0.001
E1 Service CopyRight
Electronic-Library
0.600 + 0.010
(At Seating Plane)
L/L1
0.150 MIN.
SIDE VIEW
2003
Notes:
1. All package finishes are per MIL-M-38510.
2. It is recommended that package ceramic be mounted to
a heat removal rail located on the printed circuit board.
A thermally conductive material such as MERECO XLN-589
or equivalent should be used.
3. Letter designations are for cross-reference to MIL-M-38510.
END VIEW
36-Lead Side-Brazed DIP, Dual Cavity
Packaging-10
E
0.590 ± 0.015
S1
0.005 MIN.
S2
0.005 MAX.
e
0.100
D
1.200 ± 0.025
b
0.018 ± 0.002
PIN 1 I.D.
(Geometry Optional)
SIDE VIEW
TOP VIEW
+ 0.002
C
0.010 - 0.001
E1
0.600 + 0.010
L/L1
0.150 MIN.
A
0.140 MAX.
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(AtService
SeatingCopyRight
Plane) 2003
Notes:
1. All package finishes are per MIL-M-38510.
2. It is recommended that package ceramic be mounted to
a heat removal rail located on the printed circuit board.
A thermally conductive material such as MERECO XLN-589 or
equivalent should be used.
3. Letter designations are for cross-reference to MIL-M-38510.
END VIEW
24-Lead Side-Brazed DIP, Single Cavity
Packaging-11
ORDERING INFORMATION
UT1553B RTS Remote Terminal for Stores: S
5962
*
*
*
*
*
Lead Finish:
(A) = Solder
(C) = Gold
(X) = Optional
Case Outline:
(X) = 68 pin PGA
Class Designator:
(-) = Blank or No field is QML Q
Drawing Number: 8957501
Total Dose:
(-) = None
Federal Stock Class Designator: No options
Notes:
1. Lead finish (A, C, or X) must be specified.
2. If an "X" is specified when ordering, part marking will match the lead finish and will be either "A" (solder) or "C" (gold).
3. For QML Q product, the Q designator is intentionally left blank in the SMD number (e.g. 5962-8957501XC).
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UT1553B RTS Remote Terminal for Stores
No UT Part
Number- *
*
Lead Finish:
(A) = Solder
(C) = Gold
(X) = Optional
Package Type:
(G) = 68 pin PGA
UTMC Core Part Number
Notes:
1. Lead finish (A, C, or X) must be specified.
2. If an "X" is specified when ordering, part marking will match the lead finish and will be either "A" (solder) or "C" (gold).
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