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Standard Products

CT3232M Low Power Driver / Receiver

for MIL-STD-1553B, MACAIR (A3818, A4905, A5232, A5690)

& SAE-AS15531

www.aeroflex.com/Avionics

March 15, 2005

FEATURES

❑

Compatable with MIL-STD-1553A/B & MACAIR (A3818, A4905, A5232, A5690)

±12V to ±15V/+5V DC power supply operation

1.5Watt total hybrid dissipation at 25% transmitting duty cycle

Monolithic construction

TTL compatible

Full military (-55°C to +125°C) temperature range

Driver / Receiver in a single Package for Space & Weight Savings

Filtering on Receiver to improve S/N ratio of system

Designed for commercial, industrial and aerospace applications

MIL-PRF-38534 compliant devices available

Aeroflex-Plainview is a Class H & K MIL-PRF-38534 manufacturer

Packaging – hermetic metal plug-in or flat package

24 Lead, 1.27" sq. max x .200"H Flat package

24 Pin, 1.27" sq. max x .175"H Plug-In package

DRIVER DESCRIPTION

The CT3232 Driver section accepts complementary TTL Data at the input, and produces a 30 Volt nominal

peak-to-peak differential signal across a 140Ω load at the output. When coupled to the Data Bus with a 1:1

transformer, isolated on the Data Bus side with two 55.0Ω fault isolation resistors, and loaded by two 70Ω

terminations plus additional receivers, the Data Bus signal produced is 7.2 Volts nominal peak-to-peak.

When both “DATA” and “DATA” inputs are held low or both are held high, the driver output becomes a high

impedance and is “removed” from the line. In addition, an overriding “INHIBIT” input provides for removal of the

Driver output from the line. A logic “1” applied to the “INHIBIT” takes priority over the condition of the data inputs

and disables the Driver. See Driver Logic Waveforms, Figure 3.

DATA and DATA inputs must be complementary waveforms, of 50% duty cycle average, with no gate delays

between them. It is recommended that those inputs be driven from a “D” type flip-flop.

RECEIVER DESCRIPTION

The CT3232 Receiver section accepts Bi-Phase Differential data at the input and produces two TTL signals at the

output. The outputs are “DATA” and “DATA”, and represent positive and negative excursions (respectively) of the

input beyond a predetermined threshold. See Receiver Logic Waveforms, Figure 2.

The positive and negative thresholds may be internally set by grounding the appropriate pins, or externally set with

resistors. The pre-set internal thresholds will detect Data Bus signals exceeding 1Volt p-p and ignore signals less than

0.5Volt p-p when used with 1:1 transformer (See Figure 4 for a suitable transformer and typical connection).

A low level at the STROBE input inhibits the DATA and DATA outputs. If unused, a 2KΩ pull-up to +5V is

recommended.

SCDCT3232 Rev B

CCRX

INT. DATA THRES.

+ REG

(

≈

10V )

V+

–

LEVEL

DET.

LINEAR

AMP

–

FILTER

V+

–

LEVEL

DET.

– REG

(

≈

-10V

)

V–

EXT. DATA THRES.

RX DATA OUT

RX DATA IN

STROBE

RX DATA OUT

INT. DATA THRES.

-V

EERX

GROUND A

CASE

V–

EXT. DATA THRES.

GROUND B

NOTE: GROUNDS A, B, & C

MUST ALL BE EXTERNALLY

GROUNDED

+5V

CCL

TX INHIBIT

CCTX

LINEAR

AMP

TX DATA OUT

TX DATA IN

GROUND C

TX DATA IN

LINEAR

AMP

TX DATA OUT

- V

EETX

FIGURE 1 – CT3232 Functional Block Diagram and Pinouts

SCDCT3232 Rev B

ABSOLUTE MAXIMUM RATINGS

PARAMETER

Positive Supply Voltage, Pin 4 or 13

Negative Supply Voltage, Pin 24 or 19

Logic Voltage, Pin 20

Logic Input Voltage, Pin 8, 21, 22, or 23

Receiver Differential Input, Pin 15 to Pin 16

Receiver Input Voltage, Pin 15 or Pin 16

Driver Peak Output Current, Pin 1 or Pin 2

Total Package Power Dissipation at (Ambient) T

= + 25°C

(Derate above T

= + 25°C at 40 mW/°C)

Power Dissipation at Specified Case Temperatures

Operating Case Temperature Range (T

)

(See Figure 5 for limitations)

RANGE

-0.3 to +18.0

0.3 to -18.0

-0.3 to + 7.0

-0.3 to +5.5

±20 (40Vp-p)

±15

±300

4.0 (Note 1)

See Figure 5

- 55 to + 125

°C

UNITS

Volts

Watts

ELECTRICAL CHARACTERISTICS

RECEIVER SECTION

Parameter / Condition

Power Supply Voltage Ranges

Sym

CCRX

EERX

CCL

CCRX

EERX

CCL

f = 1MHz

IDR

ICR

CMRR

Min

+11.75

-11.75

+4.75

±20

±10

2.0

Typ

Max

+15.75

-15.75

+5.25

-4

400

0.7

Unit

Supply Current

Differential Input Impedance

Differential Voltage Range

Input Common Mode Voltage Range

Common Mode Rejection Ratio (From Point A, Figure 4)

Strobe Characteristics (Logic “0” inhibits Output)

“0” Input Current (V

STROBE

= 0.5 V)

“1” Input Current (V

STROBE

= 2.7 V)

“0” Input Voltage

“1” Input Voltage

Strobe Delay (turn-on or turn-off)

Vpeak

µA

Threshold Characteristics (Sinewave input, 100KHz to 1MHz)

Note: Threshold voltages are referred to the Input

Internal (Pin 6 & 11 grounded)

External (Pin 6 & 11 open; threshold setting resistors from Pin 5

to ground & from Pin 12 to ground; R

Max = 10K

)

Filter Characteristics (Pin 6 & 11 Grounded)

(Sinewave input)

SCDCT3232 Rev B

0.6

4000

0.9

Vp-p

Ω/

Vp-p

f = 2MHz

f = 3MHz

1.0

3.0

Vp-p

ELECTRICAL CHARACTERISTICS con’t

RECEIVER SECTION

Parameter / Condition

Output Characteristics, RX Data & RX Data

“1” State (I

SOURCE

= -0.4 mA) Note 2

“0” State (I

SINK

= 4 mA) Note 2

Note: With Receiver input below threshold, both RX Data & RX Data

outputs remain in “1” state.

Delay (average) from differential input zero crossings to RX Data

& RX Data output 50% points.

Note 1: Assumes unit in free air (natural convection cooling).

Sym

Min

2.5

Typ

3.3

Max

0.5

Unit

DRX

290

450

DRIVER SECTION

Parameter / Condition

Power Supply Voltage Ranges

(See Receiver Section for V

CCL

)

Supply Current

“Standby” mode (See Receiver Section for I

CCL

)

(TX Inhibit high; or TX Data & TX Data both high or both low)

Supply Current transmitting at 1MHz into a 35

load

at point A in Figure 4

Note: I

CCL

limits do not change with mode of

operation or duty cycle

Input Characteristics, TX Data In or TX Data In

“0” Input Current (V

= 0.4 V)

“1” Input Current (V

= 2.7 V)

“0” Input Voltage

“1” Input Voltage

Inhibit Characteristic

“0” Input Current (V

= 0.4 V)

“1” Input Current (V

= 2.7 V)

“0” Input Voltage

“1” Input Voltage

Delay from TX Inhibit (0

→

1) to inhibited output impedance

Delay from TX Inhibit (1

→

0) to active output impedance

Differential Output Noise, inhibit mode

Differential output impedance (inhibited) at 1MHz

Output Characteristics (Figure 3)

Differential output level (140 ohm load)

Differential Active output impedance at 1MHz

Rise and Fall times (10% to 90% of p-p output)

Output offset at point A in Fig. 4 (35

load) 2.5µS after mid-bit

crossing of the parity bit of the last word of a 660µS message

Delay from 50% point of TX Data or TX Data input to zero

crossing of differential output

Duty Cycle

25%

100%

Sym

CCTX

EETXL

CCTXS

EETXS

CCX

EEX

CCTX

EETX

ILD

IHD

ILD

IHD

ILI

IHI

ILI

IHI

DXOFF

DXON

NOI

/ t

DTX

Min

+11.75

-11.75

Note 4

Note 3

Note 4

Note 3

2.0

10K

200

Typ

150

135

300

100

150

±20

220

Max

+15.75

-15.75

Note 2

1.0

Note 2

-1.2

100

0.7

-0.8

0.7

400

250

300

±75

350

Unit

µa

µA

PEAK

Vp-p

mVpeak

Note 2: Maximum supply currents for driver and receiver combined are included in power and thermal data table.

SCDCT3232 Rev B

ELECTRICAL CHARACTERISTICS con’t

POWER AND THERMAL DATA, TOTAL HYBRID (DRIVER AND RECEIVER) SECTION

Parameter / Condition

Total Supply Current, “Standby” mode or transmitting at less than

1% duty cycle (e.g. 20µS of transmission every 2mS or longer interval)

Total Supply Current transmitting at 1MHz into a 35

load at point A in Figure 4

Note: Iccl limits do not change with mode of operation

or duty cycle

Power Dissipation of most critical (hottest) device in

hybrid during continuous transmission

(100% duty cycle)

Thermal Resistance, junction-to-case, of most critical device

Allowable transmitting duty cycle when case is held to +100°C

maximum

Allowable transmitting duty cycle when case is held to

+125°C maximum

Supply

Voltage

±12V

±15V

Duty Cycle

25%

100%

Sym

CCS

EES

CCL

100

Supply

Voltage

±12V

±15V

Min

Note 4

Note 3

Typ

175

165

Max

190

180

Unit

Note 5

Note 3

300

450

400

600

100

°C / W

Note 5

Note 3: Decreases linearly to zero at zero duty cycle.

Note 4: Decreases linearly to applicable “Standby” value at zero duty cycle.

Note 5: Based upon operating junction temperature of 160°C for hottest device. For lower operating junction temperatures,

reduce maximum duty cycle accordingly.

90%

LINE-TO-LINE

INPUT

INPUT tr

10%

DATA

OUT

DATA

OUT

NOTE: BOTH OUTPUTS HIGH

WITH NO INPUT OR STROBE

AT LOGIC "0"

(

p-p

)

OVERLAP

≈

TH1

(p-p) x INPUT tr

0.8 x V

(

p-p

)

FIGURE 2 – Receiver Logic Waveforms

SCDCT3232 Rev B

型号	CT3232MFP	CT3232MFP102	CT3232M
描述	MIL-STD-1553 Data Bus Transceiver, 1.27 X 1.27 MM, 0.200 INCH HEIGHT, DFP-24	MIL-STD-1553 Data Bus Transceiver, MDIP24, 1.27 X 1.27 MM, 0.175 INCH HEIGHT, HERMETIC SEALED, METAL, PLUG IN-24	MIL-STD-1553 Data Bus Transceiver, MDIP24, 1.27 X 1.27 MM, 0.175 INCH HEIGHT, HERMETIC SEALED, METAL, PLUG IN-24
厂商名称	Cobham PLC	Cobham PLC	Cobham PLC
包装说明	DFP,	QIP,	QIP,
Reach Compliance Code	unknown	unknown	unknown
JESD-30 代码	S-XDFP-F24	S-MDIP-P24	S-MDIP-P24
负电源额定电压	-13.75 V	-13.75 V	-13.75 V
功能数量	1	1	1
端子数量	24	24	24
最高工作温度	125 °C	125 °C	125 °C
最低工作温度	-55 °C	-55 °C	-55 °C
封装主体材料	UNSPECIFIED	METAL	METAL
封装代码	DFP	QIP	QIP
封装形状	SQUARE	SQUARE	SQUARE
封装形式	FLATPACK	IN-LINE	IN-LINE
认证状态	Not Qualified	Not Qualified	Not Qualified
筛选级别	MIL-STD-883	MIL-STD-883	MIL-STD-883
座面最大高度	5.08 mm	4.445 mm	4.445 mm
标称供电电压	13.75 V	13.75 V	13.75 V
表面贴装	YES	NO	NO
电信集成电路类型	MIL-STD-1553 DATA BUS TRANSCEIVER	MIL-STD-1553 DATA BUS TRANSCEIVER	MIL-STD-1553 DATA BUS TRANSCEIVER
温度等级	MILITARY	MILITARY	MILITARY
端子形式	FLAT	PIN/PEG	PIN/PEG
端子节距	2.54 mm	2.54 mm	2.54 mm
端子位置	DUAL	DUAL	DUAL
宽度	-	27.94 mm	27.94 mm

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