Standard Products

UT63M147 MIL-STD-1553A/B Bus

Transceiver

Data Sheet

May 2006

FEATURES

5-volt only operation (+10%)

Fit and functionally compatible to industry standard

transceiver

Idle low transmitter inputs and receiver outputs

Dual-channel 50-mil center 24-lead Flatpack

Dual-channel 100-mil center 36-pin DIP

Full military operating temperature range, -55

癈 to +125癈,

screened to QML Q or QML V requirements

Radiation hardened to 1.0E6 rads(Si)

Supports MIL-STD-1553 (UT63M147)

Standard Microcircuit Drawing (SMD) 5962-93226 available

INTRODUCTION

The monolithic UT63M147 Transceivers are complete
transmitter and receiver pairs for MIL-STD-1553A and 1553B
applications. Encoder and decoder interfaces are idle low.

The receiver section of the UT63M147 series accepts biphase-
modulated Manchester II bipolar data from a MIL-STD-1553
data bus and produces TTL-level signal data at its RXOUT and
RXOUT outputs. An external RXEN input enables or disables
the receiver outputs.

TXIN

RXOUT

RXEN

TO DECODER

DRIVERS

COMPARE

ILTER

LIMITER

and

ILTER

TXIHB

Figure 1. Functional Block Diagram

RXIN

TXOUT

RXIN

TXOUT

RXOUT

TXIN

THRESHOLD
REFERENCE

Appendix 2 - 2

The transmitter section accepts biphase TTL-level signal data
at its TXIN and TXIN and produces MIL-STD-1553 data
signals. The transmitter's output voltage is typically
12 V

PP, L-L

. Activating the TXIHB input or setting both data

inputs to the same logic level disables the transmitter outputs.

The UT63M14x series offers complete transmitter and receiver
pairs packaged in a dual-channel 36-pin DIP or 24-lead flatpack
configurations designed for use in any MIL-STD-1553
application.

Legend for TYPE field:

TI = TTL

input

TO = TTL

output

DO = Differential

output

DI = Differential

input

DIO = Differential input/output
( )

= Channel designator

[ ]

= 24-lead flatpack

TRANSMITTER

Note:

1. The 24-lead flatpack internally connects TXOUT to RXIN (CHA, CHB) and TXOUT to RXIN (CHA, CHB) for each channel.

NAME

PIN

NUMBER

TYPE

DESCRIPTION

TXOUT

(A)

TXOUT

(B)

1 [1]

10 [7]

[DIO]

Transmitter outputs: TXOUT and TXOUT are differential data
signals.

TXOUT

(A)

TXOUT

(B)

2 [2]

11 [8]

[DIO]

TXOUT is the half-cycle complement of TXOUT.

TXIHB

(A)

TXIHB

(B)

34 [22]

25 [16]

Transmitter inhibit: This is an active high input signal.

TXIN

(A)

TXIN

(B)

35 [23]

26 [17]

Transmitter input: TXIN and TXIN are complementary TTL-
level Manchester II encoder inputs.

TXIN

(A)

TXIN

(B)

36 [24]

27 [18]

TXIN is the complement of TXIN input.

Appendix 2 - 3

RECEIVER

Note:
1. The 24-lead flatpack internally connects TXOUT to RXIN (CHA, CHB) and TXOUT to RXIN (CHA, CHB) for each channel.

POWER AND GROUND

NAME

PIN

NUMBER

TYPE

DESCRIPTION

RXOUT

(A)

RXOUT

(B)

5 [4]

14 [10]

Receiver outputs: RXOUT and RXOUT are complementary
Manchester II decoder outputs.

RXOUT

(A)

RXOUT

(B)

8 [6]

17 [12]

RXOUT is the complement of RXOUT output.

RXEN

(A)

RXEN

(B)

6 [5]

15 [11]

Receiver enable/disable: This is an active high input signal.

RXIN

(A)

RXIN

(B)

29 [1]

20 [7]

[DIO]

Receiver input: RXIN and RXIN are biphase-modulated
Manchester II bipolar inputs from MIL-STD-1553 data bus.

RXIN

(A)

RXIN

(B)

30 [2]

21 [8]

[DIO]

RXIN is the half-cycle complement of RXIN input.

NAME

PIN

NUMBER

TYPE

DESCRIPTION

(A)

(B)

33 [20]

24 [14]

PWR

+5 V

power (

�10%)

Recommended decoupling capacitors:
47

礔 (tantalum), 0.1礔 (ceramic) and 0.01礔 (ceramic)

GND

(A)

GND

(B)

3, 7, 31

[3,19,21]

12, 16, 22

[9,13,15]

GND

Ground reference

Appendix 2 - 4

14
15

17
18

33
32

31
30
29

25
24
23

22
21

20
19

2
3

4
5

7
8

TXOUT

RXOUT

TXOUT

GND

RXOUT
RXEN
GND

TXOUT

RXOUT

TXOUT

GND

RXOUT
RXEN
GND

TXIN

RXIN

TXIN

TXIHB

NC
GND

RXIN

TXIN

RXIN

TXIN

TXIHB

NC
GND

RXIN
NC

CHANNEL A

CHANNEL B

Figure 2a. Functional Pin Diagram -- Dual Channel (36)

11
12

21
20

16
15
14

2
3

4
5

CHA

GND

RXOUT
RXEN

CHB

GND

RXOUT
RXEN

TXIN

TXIHB

GND

TXIN

TXIHB

GND

CHANNEL A

CHANNEL B

Figure 2b. Functional Pin Diagram -- Dual Channel (24)

RXOUT

GND

Note:

1. The 24-lead flatpack internally connects TXOUT to RXIN (CHA, CHB) and TXOUT to RXIN (CHA, CHB) for each channel.

Appendix 2 - 5

TRANSMITTER

The transmitter section accepts Manchester II biphase TTL data
and converts this data into differential phase-modulated current
drive. Transmitter current drivers are coupled to a MIL-STD-
1553 data bus via a transformer driven from the TXOUT and
TXOUT terminals. Transmitter output terminals' non-
transmitting state is enabled by asserting TXIHB (logic "1"), or
by placing both TXIN and TXIN at the same logic level. Table
1, Transmit Operating Mode, lists the functions for the output
data in reference to the state of TXIHB. Figure 3 shows typical
transmitter waveforms.

RECEIVER

The receiver section accepts biphase differential data from a
MIL-STD-1553 data bus at its RXIN and RXIN inputs. The
receiver converts input data to biphase Manchester II TTL
format and is available for decoding at the RXOUT and RXOUT
terminals. The outputs RXOUT and RXOUT represent positive
and negative excursions (respectively) of the inputs RXIN and
RXIN. Figure 4 shows typical receiver output waveforms.

Table 1. Transmit Operating Mode

Notes:
1. x = Don't care.
2. Transmitter output terminals are in the non-transmitting mode during
Off-time.
3. Transmitter output terminals are in the non-transmitting mode during
Off-time, independent of TXIHB status.

Figure 3. Typical Transmitter

Wave

Figure 4. Typical Receiver Waveforms

TXIN

TXIHB

TXOUT

90%

10%

TXOUT, TXOUT

TXIN

LINE-TO-LINE
DIFFERENTIAL
OUTPUT

TXIN

TXIHB

TXIN

TXDD

BOTH HIGH
OR
BOTH LOW

RXOUT

LINE-TO-LINE
DIFFERENTIAL
INPUT

RXDD

Off

Appendix 2 - 6

DATA BUS INTERFACE

The designer can connect the UT63M14x to the data bus via a
short-stub (direct-coupling) connection or a long-stub
(transformer-coupling) connection. Use a short-stub connection
when the distance from the isolation transformer to the data bus
does not exceed a one-foot maximum. Use a long-stub
connection when the distance from the isolation transformer
exceeds the one-foot maximum and is less than twenty feet.
Figure 5 shows various examples of bus coupling
configurations. The UT63M14x series transceivers are designed
to function with MIL-STD-1553A and 1553B compatible
transformers.

Note:

1. The 24-lead flatpack internally connects TXOUT to RXIN and TXOUT to
RXIN for each channel.

RECOMMENDED THERMAL PROTECTION

All packages should mount to or contact a heat removal rail
located in the printed circuit board. To insure proper heat
transfer between the package and the heat removal rail, use a
thermally-conductive material between the package and the heat
removal rail. Use a material such as Mereco XLN-589 or
equivalent to insure heat transfer between the package and heat
removal rail.

Figure 8. Transceiver Test Circuit MIL-STD-1553B

Figure 5. Bus Coupling Configuration

55 OHMS

20 FT MAX

1:1.4

Note:
Z

defined per MIL-STD-1553B, Section 4.5.1.5.2.1.

+5V DC OPERATION

1:1.79

1:2.5

SHORT-STUB
DIRECT COUPLING
1 FT. MAX.

LONG-STUB
TRANSFORMER COUPLING

.75 Z

TXOUT

RXIN

TXOUT

Appendix 2 - 7

RL =

15 pF

55 OHMS

35 OHMS

RECEIVER

TRANSMITTER

RXIN

RXEN

RXOUT

Figure 6. Direct Coupled Transceiver with Load

55 OHMS

35 OHMS

TXOUT

TXIN

RXIN

RXOUT

TXIN

TXIHB

TXOUT

2KOHMS

2.5:1

1:2.5

Notes:
1. TP = Test point.
2. RL removed for terminal

input impedance test.

3. TXOUT and RXIN tied together.

TXOUT and RXIN tied together.

1:1.4

15 pF

RECEIVER

TRANSMITTER

35 OHMS

RXEN

1.79:1

1.4:1

RXOUT

1:1.79

RXIN

TXIN

TXIHB

TXOUT

RXOUT

2KOHMS

Notes:
1. TP = Test point.
2. RL removed for terminal impedance test.
3. TXOUT and RXIN tied together.

TXOUT and RXIN tied together.

Figure 7. Transformer Coupled Transceiver with Load

.75 Z

Appendix 2 - 8

ABSOLUTE MAXIMUM RATINGS

Notes:
1. Stress outside the listed absolute maximum rating may cause permanent damage to the devices. This is a stress rating 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.
2. Mounting per MIL-STD-883, Method 1012.

RECOMMENDED OPERATING CONDITIONS

PARAMETER

LIMITS

UNIT

-0.3 to +7.0

Input voltage range (receiver)

PP,

L-L

Logic input voltage range

-0.3 to +5.5

Power dissipation 100% duty cycle (per channel)

3.6

Thermal impedance junction to case

6.0

癈/W

Maximum junction temperature

+175

癈

Storage temperature

-65 to +150

癈

Receiver common mode input voltage range

-5.0 to +5.0

PARAMETER

LIMITS

UNIT

Supply voltage range

+4.50 to +5.50

Logic input voltage range

0 to +5.0

Receiver differential voltage

8.0

P-P

Receiver common mode voltage range

+4.0

Driver peak output current

600

Serial data rate

0.3 to 1

MHz

Case operating temperature range (T

)

-55 to +125

癈

TERMINAL

Notes:
1. Transformer Coupled Stub:

Terminal is defined as transceiver plus isolation transformer. Point A is defined in figure 7.

2. Direct Coupled Stub:

Terminal is defined as transceiver plus isolation transformer and fault resistors. Point A is defined in figure 6.

TXOUT

Figure 8. Transceiver Test Circuit MIL-STD-1553

Appendix 2 - 9

DC ELECTRICAL CHARACTERISTICS

= 5.0V

�10%

-55

癈 < T

< +125

癈

Note:
1. All tests guaranteed per test figure 6.
2. Guaranteed but not tested.

SYMBOL

PARAMETER

MINIMUM

MAXIMUM

UNIT

CONDITION

Input low voltage

0.8

RXEN, TXIHB, TXIN, TXIN

Input high voltage

2.0

RXEN, TXIHB, TXIN, TXIN

Input low current

-0.1

= 0.4V; RXEN, TXIHB, TXIN,

TXIN

Input high current

-40

礎

= 2.7V; RXEN, TXIHB, TXIN,

TXIN

Output low voltage

.55

= 4mA; RXOUT, RXOUT

Output high voltage

2.4

= 0.4mA; RXOUT, RXOUT

supply current

200
380
650
740

mA
mA
mA
mA
mA

0% duty cycle (non-transmitting)
25% duty cycle (

= 1MHz)

50% duty cycle (

= 1MHz)

87.5% duty cycle (

= 1MHz)

100% duty cycle (

= 1MHz)

Appendix 2 - 10

RECEIVER ELECTRICAL CHARACTERISTICS

= 5.0V

�10%

-55

癈 < T

< +125

癈

Notes:
1. All tests guaranteed per test figure 6.
2. Capacitance is measured only for initial qualification and after any process or design changes which may affect input or output capacitance.
3. Pass/fail criteria per the test method described in MIL-HDBK-1553 Appendix A, RT Validation Test Plan, Section 5.1.2.2, Common Mode Rejection.
4. Guaranteed by design.
5. Guaranteed to the limits specified if not tested.

SYMBOL

PARAMETER

MINIMUM

MAXIMUM

UNIT

CONDITION

Input capacitance

RXEN; input

= 1MHz @ 0V

OUT

Output capacitance

RXOUT, RXOUT;

= 1MHz @ 0V

Common mode input
voltage

-5

Direct-coupled stub; input 1.2 V

200ns rise/fall time

�25ns,

= 1MHz

Input threshold
voltage

(no response)

Input threshold voltage
(no response)

Input threshold
voltage

(response)

Input threshold voltage
(response)

0.86

1.20

0.20

0.28

14.0

20.0

PP,L-L

Transformer-coupled stub; input at
= 1MHz, rise/fall time 200ns at
(Receiver output 0

1 transition)

Direct-coupled stub; input at

= 1MHz,

rise/fall time 200ns at (Receiver output
0

1 transition)

Transformer-coupled stub; input at

= 1MHz, rise/fall time 200ns at
(Receiver output 0

1 transition)

Direct-coupled stub; input at

= 1MHz,

rise/fall time 200ns at (Receiver output
0

1 transition)

CMRR

Common mode
rejection ratio

Pass/Fail

N/A

Appendix 2 - 11

TRANSMITTER ELECTRICAL CHARACTERISTICS

= 5.0V

�10%

-55

癈 < T

< +125

癈

Notes:
1. All tests guaranteed per test figure 6.
2. Guaranteed by device characterization. Capacitance is measured only for initial qualification and after any process or design changes which may affect
input or output capacitance.
3. For MIL-STD-1760, 22 Vp-p, L-L min.
4. Test in accordance with the method described in MIL-STD-1553B output symmetry, section 4.5.2.1.1.4.
5. Guaranteed to the limits specified if not tested.

SYMBOL

PARAMETER

MINIMUM

MAXIMUM

UNIT

CONDITION

Output voltage swing per
MIL-STD-1553B

3, 5

(see figure 9)

per MIL-STD-1553B
(see figure 9)

per MIL-STD-1553A

(see figure 9)

6.0

9.0

PP,L-L

Transformer-coupled stub, Figure 8,
Point A; input

= 1MHz,

= 70 ohms

Direct-coupled stub, Figure 8, Point
A; input

= 1MHz,

= 35 ohms

Figure 7, Point A; input

= 1MHz, R

= 35 ohms

Output noise voltage
differential (see figure 9)

mV-RMS

L-L

mV-RMS

L-L

Transformer-coupled stub, Figure 8,
Point A; input

= DC to 10MHz, R

= 70 ohms

Direct-coupled stub, Figure 8, Point
A; input

= DC to 10MHz,

= 35 ohms

Output symmetry

-250

-90

+250

+90

PP,L-L

Transformer-coupled stub, Figure 8,
Point A; R

= 140 ohms,

measurement taken 2.5

祍 after end

of transmission

Direct-coupled stub, Figure 8, Point
A; R

= 35 ohms, measurement

taken 2.5

祍 after end of transmission

DIS

Output voltage
distortion (overshoot or
ring) (see figure 9)

-900

-300

+900

+300

peak,L-L

Transformer-coupled stub, Figure 8,
Point A; R

= 70 ohms

Direct-coupled stub, Figure 8, Point
A; R

= 35 ohms

Input capacitance

RXEN, TXIHB, TXIN, TXIN; input

= 1MHz @ 0V

Terminal input
impedance

Kohm

Transformer-coupled stub, Figure 7,
Point A; input

= 75KHz to 1MHZ

(power on or power off; non-
transmitting, R

removed from

circuit).

Direct-coupled stub, Figure 6, Point
A; input

= 75KHz to 1MHZ (power

on or power off; non-transmitting,
R

removed from circuit).

Appendix 2 - 12

AC ELECTRICAL CHARACTERISTICS

= 5.0V

�10%

-55

癈 < T

< +125

癈

Notes:
1. All tests guaranteed per test figure 6.
2. Guaranteed by device characterization.
3. Supplied as a design limit but not guaranteed or tested.
4. Delay time from transmit inhibit (1.5V) rising to transmit off (280mV).
5. Delay time from not transmit inhibit (1.5V) falling to transmit off (1.2V).

SYMBOL

PARAMETER

MINIMUM

MAXIMUM

UNIT

CONDITION

Transmitter output rise/
fall time (see figure 10)

100

300

Input

= 1MHz 50% duty cycle:

direct-coupled R

= 35 ohms output

at 10% through 90% points TXOUT,
TXOUT. Figure 10.

RXDD

RXOUT delay

-200

200

RXOUT to RXOUT, Figure 4.

TXDD

TXIN skew

-25

TXIN to TXIN, Figure 3.

RZCD

Zero crossing distortion
(see figure 11)

-150

150

Direct-coupled stub; input

= 1MHz,

3 V

(skew INPUT

�150ns), rise/fall

time 200ns.

TZCS

Zero crossing stability
(see figure 11)

-25

Input TXIN and TXIN should create
Transmitter output zero crossings at
500ns, 1000ns, 1500ns, and 2000ns.
These zero crossings should not
deviate more than

�25ns.

RDXOFF

3,4

Transmitter off; delay
from inhibit active

100

TXIN and TXIN toggling @ 1MHz;
TXIHB transitions from logic zero to
one, see figure 12.

DXON

3,5

Transmitter on; delay
from inhibit inactive

150

TXIN and TXIN toggling @ 1MHz;
TXIHB transitions from logic one to
zero, see figure 13.

RCVOFF

Receiver off

Receiver turn off time, see figure 13.

RCVON

Receiver on

Receiver turn on time, see figure 13.

RCVPD

Receiver propagation

450

Receiver propagation delay, see
figure 13.

XMITPD

Transmitter
propagation

200

Transmitter propagation delay, see
figure 12.

Table 2. Transformer Requirements

COUPLING TECHNIQUE

� 5V

DIRECT-COUPLED:
Isolation Transformer Ratio

2.5:1

TRANSFORMER-COUPLED:
Isolation Transformer Ratio

1.79:1

Coupling Transformer Ratio

1:1.4

Appendix 2 - 13

Figure 9. Transmitter Output Characteristics (V

DIS

, V

)

Figure 10. Transmitter Output Zero Crossing Stability, Rise Time, Fall Time (t

TZCS

, t

)

Figure 11. Receiver Input Zero Crossing Distortion (t

RZCD

)

0 Volts

DIS

(Ring)

DIS

(Overshoot)

90%

10%

90%

TZCS

RZCD

Figure 14. 36-Pin Side-Brazed DIP, Dual Cavity

Notes:
1. Package material: opaque ceramic.
2. All package finishes are per MIL-PRF-38535.
3. It is recommended that package ceramic be mounted on a heat removal
rail in the printed circuit board. A thermally conductive material should
be used.

LEAD 1
INDICATOR

0.005 MIN.

.610 MAX.
.570 MIN.

.015 MAX.
.008 MIN.

.620 MAX.
.590 MIN.

(AT SEATING PLANE)

1.89 MAX.

0.001 MIN.

.023 MAX.
.014 MIN.

0.155
MAX.

0.150
MIN.

0.100

Appendix 2 - 16

Figure 15. 24-Lead Flatpack, Dual Cavity

(50-mil lead spacing)

Notes:
1. Package material: opaque ceramic.
2. All package plating finishes are per MIL-PRF-38535.
3. It is recommended that package ceramic be mounted to a heat removal rail located in the
printed circuit board. A thermally conductive material should be used.

.810 MAX.

.600 MAX.

.400 MIN.

LEAD 1 INDICATOR

0.130 MAX.

0.070

�

0.010

(AT CERAMIC BODY)

.050

0.016

�

.002

.010 + .002 - .001

Figure 15. 24-Lead Flatpack, Dual Cavity

(50-mil lead spacing)

.810 MAX.

.600 MAX.

.400 MIN.

LEAD 1 INDICATOR

0.130 MAX.

0.070

�

0.010

(AT CERAMIC BODY)

.050

0.016

�

.002

.010 + .002 - .001

ORDERING INFORMATION

UT63M14x Monolithic Transceiver, 5V Operation: SMD

Lead Finish:

(A) = Solder

(X) = Optional

Case Outline:

(X) = 36 pin DIP

(Z) = 24 pin FP

Class Designator:

(Q) = Class Q

(V) = Class V

Device Type

(03) = Idle low

Drawing Number: 93226

Total Dose:

(H) = 1E6 rads(Si)

(G) = 5E5 ads(Si)

(F) = 3E5 rads(Si)

(R) = 1E5rads(Si)

(-) = None

Federal Stock Class Designator: No options

5962 * 93226 * * * *

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. Total dose must be specified for all QML Q and QML V devices.
4. Neutron irradiation limits will be added when available.

UT63M14x Monolithic Transceiver, 5V Operation

Total Dose:
()

= None

Lead Finish:
(A) = Solder
(C) = Gold
(X) = Optional

Screening:

(P) = Prototype

Package Type:

(B) = 36-pin DIP

Device Type Modifier:

147 = Idle Low Transceiver

UT63M- * * * *

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. Military Temperature range devices are burned-in and tested at -55

癈, room temperature, and 125癈. Radiation characteristics are neither tested nor

guaranteed and may not be specified.

4. Devices have prototype assembly and are tested at 25

癈 only. Radiation characteristics are neither tested nor guaranteed and may not be specified.

Lead finish is GOLD only.

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Tel: 949-362-2260
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Tel: 719-594-8017
Fax: 719-594-8468

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changes to any products and services herein at any time

without notice. Consult Aeroflex or an authorized sales

representative to verify that the information in this data sheet

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协谢械泻褌褉芯薪薪褘泄 泻芯屑锌芯薪械薪褌: UT63M147CCA

协谢械泻褌褉芯薪薪褘泄泻芯屑锌芯薪械薪褌: UT63M147CCA