SP207HBET/TR - Sipex Corporation

Now available in Lead Free

Table 1. Model Selection Table

SP207H/SP211H

+5V High–Speed RS-232 Transceiver s

■Single 5V Supply Operation

■0.1µF External Charge Pump Capacitors

■460kbps Minimum Data Rate

■Standard SOIC and SSOP Packages

■SP207H - Five (5) Drivers and Three (3)

Receivers

SP211H - Four (4) Drivers and Five (5)

Receivers

■1µA Shutdown Mode

■WakeUp Feature in Shutdown Mode

■Tri–State Receiver Outputs

■Ideal for V.34 and High Speed RS-232

Applications

Number of RS-232 No. of Receivers No. of External

Model Drivers Receivers Active in Shutdown 0.1µF Capacitors Shutdown WakeUp TTL Tri–State

SP207H 5 3 0 4 No No No

SP207HB 5 3 3 4 Yes Yes Yes

SP211H 4 5 0 4 Yes No Yes

SP211HB 4 5 5 4 Yes Yes Yes

+5V INPUT

400KOHM

OUT

0.1µF

6.3V 0.1µF

6.3V

0.1µF

16V

0.1µF

16V

0.1µF

6.3V

–

400KOHM

OUT

400KOHM

OUT

400KOHM

OUT

OUT R

SP207

TTL/CMOS INPUTS

RS-232 OUTPUTS

GND

OUT R

TTL/CMOS OUTPUTS

RS-232 INPUTS

5KOHM

400KOHM

OUT

21 20

+5V INPUT

400KOHM

OUT

0.1µF

6.3V 0.1µF

6.3V

0.1µF

16V

0.1µF

16V

0.1µF

6.3V

–

400KOHM

OUT

400KOHM

OUT

400KOHM

OUT

OUT R

SP211

TTL/CMOS INPUTS

RS-232 OUTPUTS

GND

OUT R

26 27

TTL/CMOS OUTPUTS

RS-232 INPUTS

5KOHM

OUT R

22 23

5KOHM

OUT R

19 18

5KOHM SD

DESCRIPTION…

The SP207H and SP211H are multi–channel RS-232 line transceivers configured to fit most

communication needs. The "H" series is based on Sipex's SP200 Series transceivers and has

been enhanced for speed. The data rate is improved to over 460kbps which easily meets the

230.4kbps data rates for V.34. The SP207H and SP211H use the same on-board charge pump

to provide ±10V voltage levels, using 0.1µF charge pump capacitors to save board space and

reduce circuit cost. The SP207HB, SP211H and SP211HB feature a low–power shutdown

mode, which reduces power supply drain to 1µA. A WakeUp function keeps the receivers active

in the shutdown mode (SP207HB and SP211HB only).

ABSOLUTE MAXIMUM RATINGS

These are stress ratings only and functional operation of the device

at these or any other above those indicated in the operation

sections of the specifications below is not implied. Exposure to

absolute maximum rating conditions for extended periods of time

may affect reliability.

VCC ............................................................................................ +6V

V+................................................................. (VCC – 0.3V) to +13.2V

V–........................................................................................... 13.2V

Input Voltages

TxIN ................................................................. –0.3V to (VCC +0.3V)

RxIN ....................................................................... ±30V at ≤100mA

Output Voltages

TOUT .......................................................... (V+, +0.3V) to (V–, –0.3V)

ROUT ................................................................. –0.3V to (VCC +0.3V)

Short Circuit Duration on TOUT ....................................... Continuous

Power Dissipation

Plastic DIP .......................................................................... 375mW

(derate 7mW/°C above +70°C)

Small Outline ...................................................................... 375mW

(derate 7mW/°C above +70°C)

SPECIFICATIONS

VCC at nominal ratings; 0.1µF charge pump capacitors; TMIN to TMAX, unless otherwise noted.

PARAMETER MIN. TYP. MAX. UNIT CONDITIONS

TTL INPUTS (DRIVER) TIN, EN, SD

Logic Threshold

VIL 0.8 Volts

VIH 2.0 Volts

Logic Pullup Current 1.5 10.0 µAT

IN = 0V

Data Rate 460 600 kbps CL = 1,000pF, RL = 3kΩ

TTL OUTPUTS (RECEIVER) ROUT

Compatibility TTL/CMOS

VOL 0.4 Volts IOUT = 3.2mA; VCC = +5V

VOH 3.5 Volts IOUT = –1.0mA

Leakage Current 0.05 ±10 µAEN = VCC; 0V ≤ ROUT ≤ VCC ;

TA = +25°C

RS-232 OUTPUT (DRIVER)

Output Voltage Swing ±5±7 Volts All transmitter outputs loaded

with 3kΩ to ground

Power-Off Output Resistance 300 Ohms VCC = 0V; VOUT = ±2V

Output Short Circuit Current ±25 mA Infinite duration

RS-232 INPUT (RECEIVER)

Voltage Range –15 +15 Volts

Logic Pull Down Current 3.0 10.0 µAT

= +25°C

Voltage Threshold

VIL 0.8 1.2 Volts VCC = +5V, TA = +25°C

VIH 1.7 2.4 Volts VCC = +5V, TA = +25°C

Hysteresis 0.2 0.5 1.0 Volts VCC = +5V

Resistance 3 5 7 kΩVIN = ±15V; TA = +25°C

Data Rate 460 600 kbps

DYNAMIC CHARACTERISTICS

Propagation Delay 1.0 µs TTL–to–RS-232

1.5 µs RS-232–to–TTL

Instantaneous Slew Rate 60 V/µsC

= 50pF, RL = 3–7kΩ;

TA = +25°C

Transition Region Slew Rate 5 V/µsC

= 1,000pF, RL = 3kΩ;

measured from +3V to

–3V or –3V to +3V

SPECIFICATIONS

VCC at nominal ratings; 0.1µF charge pump capacitors; TMIN to TMAX, unless otherwise noted.

PARAMETER MIN. TYP. MAX. UNIT CONDITIONS

Output Enable Time 400 ns

Output Disable Time 250 ns

POWER REQUIREMENTS

VCC 4.75 5.00 5.25 Volts

ICC 5 10 mA No load; VCC = 5V; TA = +25°C

20 mA All transmitters RL = 3kΩ; TA = +25°C

Shutdown Current 1 10 µA TA = +25°C

ENVIRONMENTAL AND MECHANICAL

Operating Temperature

Commercial, –C 0 +70 °C

Extended, –E –40 +85 °C

Storage Temperature –65 +125 °C

Package

–A Shrink (SSOP) small outline

–T Wide (SOIC) small outline

PINOUT

FEATURES…

The SP207H and SP211H line transceivers

provide a variety of configurations to fit most

communication needs, especially those applica-

tions where ±12V is not available. Both prod-

ucts feature low–power CMOS construction

and Sipex–proprietary on-board charge pump

circuitry to generate the ±10V RS-232 voltage

levels. The ability to use 0.1µF charge pump

capacitors saves board space and reduces circuit

cost.

The SP207HB and SP211H models feature a

low–power shutdown mode, which reduces

power supply drain to 1µA. The SP207HB and

SP211HB are equipped with the WakeUp func-

tion. The WakeUp function keeps the receivers

active in the shutdown mode, unless disabled by

the EN pin.

SP211

OUT

GND

V+

–

OUT

SHUTDOWN (SD)

OUT

V–

–

SP211B

OUT

GND

V+

–

OUT

SHUTDOWN (SD)

OUT

V–

–

SP207B

OUT

GND

V+

–

OUT

SHUTDOWN (SD)

OUT

V–

–

SP207

T3 OUT

T1OUT

T2OUT

R1IN

R1OUT

T2IN

T1IN

GND

VCC

C1+

V+

C1–

T4 OUT

R2IN

R2OUT

T5IN

T5OUT

T4IN

T3IN

R3OUT

R3IN

V–

C2–

C2+

THEORY OF OPERATION

The SP207H and SP211H are made up of three

basic circuit blocks — 1) transmitter/driver, 2)

receiver and 3) the Sipex–proprietary charge

pump.

Charge–Pump

The charge pump is a Sipex–patented design

(5,306,954) and uses a unique approach com-

pared to older less–efficient designs. The charge

pump still requires four external capacitors, but

uses a four–phase voltage shifting technique to

attain symmetrical 10V power supplies. Figure

3a shows the waveform found on the positive

side of capcitor C2, and Figure 3b shows the

Figure 2. Charge Pump — Phase 2

negative side of capcitor C2. There is a free–

running oscillator that controls the four phases

of the voltage shifting. A description of each

phase follows.

Phase 1

— VSS charge storage —During this phase of the

clock cycle, the positive side of capacitors C1

and C2 are initially charged to +5V. Cl+ is then

switched to ground and the charge in C1– is

transferred to C2–. Since C2+ is connected to

+5V, the voltage potential across capacitor C2 is

now 10V.

Phase 2

— VSS transfer — Phase two of the clock con-

nects the negative terminal of C2 to the VSS

storage capacitor and the positive terminal of C2

to ground, and transfers the generated –l0V to

C3. Simultaneously, the positive side of capaci-

tor C 1 is switched to +5V and the negative side

is connected to ground.

Phase 3

— VDD charge storage — The third phase of the

clock is identical to the first phase — the charge

transferred in C1 produces –5V in the negative

terminal of C1, which is applied to the negative

side of capacitor C2. Since C2+ is at +5V, the

voltage potential across C2 is l0V.

Phase 4

— VDD transfer — The fourth phase of the clock

connects the negative terminal of C2 to ground,

and transfers the generated l0V across C2 to C4,

the VDD storage capacitor. Again, simultaneously

with this, the positive side of capacitor C1 is

switched to +5V and the negative side is con-

nected to ground, and the cycle begins again.

Since both V+ and V– are separately generated

from VCC; in a no–load condition V+ and V– will

be symmetrical. Older charge pump approaches

that generate V– from V+ will show a decrease in

the magnitude of V– compared to V+ due to the

inherent inefficiencies in the design.

The clock rate for the charge pump typically

operates at 15kHz. The external capacitors can

be as low as 0.1µF with a 16V breakdown

voltage rating.

Transmitter/Driver

The drivers are inverting transmitters which have

been improved for speed over the SP200 Series.

The transmitters accept either TTL or CMOS

inputs and output the RS-232 signals at data rates

over 400kbps. Typically, the RS-232 output volt

= +5V

–5V –5V

+5V

Storage Capacitor

–

––

Figure 1. Charge Pump — Phase 1

= +5V

–10V

Storage Capacitor

–

––

Figure 4. Charge Pump — Phase 3

age swing is ±9V with no load, and ±5V minimum

with full load. The transmitter outputs are pro-

tected against infinite short–circuits to ground

without degradation in reliability. The SP207HB,

SP211H and SP211HB drivers can be tri–stated

by using the SHUTDOWN function.

In the “power off” state, the output impedance will

remain greater than 300 ohms, again satisfying the

RS-232 specifications. Should the input of the

driver be left open, an internal 400Kohm pullup

resistor to VCC forces the input high, thus commit-

ting the output to a low state.

Because of the increased speed, the slew rate is

typically 60V/µS which is above the RS-232

specifcation of 30V/µS. This is the only param-

eter that exceeds the RS-232 limits.

Figure 3. Charge Pump Waveforms

+10V

a) C2+

GND

b) C2–

–10V

= +5V

–5V

+5V

–5V

Storage Capacitor

–

––

Receivers

The receivers convert RS-232 input signals to

inverted TTL signals. Since the input is usually

from a transmission line where long cable lengths

and system interference can degrade the signal,

the inputs have a typical hysteresis margin of

500mV. This ensures that the receiver is virtu-

ally immune to noisy transmission lines. Should

an input be left unconnected, a 5Kohm pulldown

resistor to ground will commit the output of the

receiver to a high state.

Power Receiver

SD EN Up/Down Outputs

0 0 Up Enable

0 1 Up Tri–state

1 0 Down Tri-state

1 1 Down Tri–state

SHUTDOWN MODE

The SP207HB, SP211H and SP211HB all fea-

ture a control input which will disable the device

and reduce the power supply current to less than

10µA, making the parts ideal for battery–pow-

ered systems. In the “shutdown” mode the re-

ceivers and transmitters will both be tri–stated.

The V+ output of the charge pump will discharge

to VCC , and the V– output will discharge to

ground.

For complete shutdown to occur and the 10µA

power drain to be realized, the following condi-

tions must be met:

• +5V must be applied to the SD pin

• ENABLE must be either 0V, +5.0V or not

connected

• the transmitter inputs must be either +5.0V

or not connected

• VCC must be +5V

• Receiver inputs must be >0V and <+5V

ENABLE

The SP207HB, SP211H and SP211HB feature

an enable input pin, which allows the receiver

= +5V

+10V

Storage Capacitor

–

––

Table 2. Truth Table for SP2xxH

Power Receiver

SD EN Up/Down Outputs

0 0 Up Enable

0 1 Up Tri–state

1 0 Down Enable

1 1 Down Tri–state

Table 3. Wake–Up Truth Table for SP2xxHB

Figure 5. Charge Pump — Phase 4

outputs to be either tri–stated or enabled. This

can be especially useful when the receiver is tied

directly to a microprocessor data bus. The en-

able is active low; that is, 0V applied to the

ENABLE pin will enable the receiver outputs.

WAKEUP FUNCTION

The SP207HB and SP211HB have a wake–up

feature that keeps all the receivers in an enabled

state when the device is in the shutdown mode.

With only the receivers active during shutdown,

the devices draw 5–10µA of supply current. A

typical application of this function would be

where a modem is interfaced to a computer in a

power–down mode. The ring indicator signal

from the modem could be passed through an

active receiver that is in the shutdown mode.

The ring indicator signal would propagate

through the receiver to the power management

circuitry of the computer to power up the micro-

processor and the SP207HB/SP211HB drivers.

After the supply voltage to the transceivers

reaches +5.0V, the SHUTDOWN pin can be

disabled. All receivers that are active during

shutdown maintain 500mV (typ.) of hysteresis.

Figure 6. Wake–Up Timing

+5V

ENABLE

DISABLE

OUT

DATA VALID

+5V

OUT

+5V

OUT

WAIT

0 (POWERUP)

ENABLE

DISABLE

POWER UP WITH SD ACTIVE (Charge pump in shutdown mode)

POWER UP WITH SD DISABLED (Charge pump in active mode)

0 (POWERUP)

ENABLE

DATA VALID

DATA VALID DATA VALID DATA VALID

EXERCISING WAKE–UP FEATURE

0 (POWERUP)

ENABLE

WAIT

DISABLE DISABLEENABLE

WAIT

= 2ms typical, 3ms maximum

ENABLE

= 1ms typical, 2ms maximum

= +5V ±10%; T

= 25°C

TYPICAL APPLICATION CIRCUITS

+5V INPUT

400KOHM

OUT

0.1µF

6.3V 0.1µF

6.3V

0.1µF

16V

0.1µF

16V

0.1µF

6.3V

–

400KOHM

OUT

400KOHM

OUT

400KOHM

OUT

OUT R

SP207

TTL/CMOS INPUTS

RS-232 OUTPUTS

GND

OUT R

TTL/CMOS OUTPUTS

RS-232 INPUTS

5KOHM

400KOHM

OUT

21 20

+5V INPUT

400KOHM

OUT

0.1µF

6.3V 0.1µF

6.3V

0.1µF

16V

0.1µF

16V

0.1µF

6.3V

–

400KOHM

OUT

400KOHM

OUT

400KOHM

OUT

OUT* R

IN*

SP207B

TTL/CMOS INPUTS

RS-232 OUTPUTS

GND

OUT* R

IN*

TTL/CMOS OUTPUTS

RS-232 INPUTS

5KOHM

OUT* R

IN*

19 18

5KOHM SD

*Receivers active during shutdown

400KOHM

OUT

26 23

The SP207B is offered in a 28–pin SOIC or 28–pin SSOP package.

+5V INPUT

400KOHM

OUT

0.1µF

6.3V 0.1µF

6.3V

0.1µF

16V

0.1µF

16V

0.1µF

6.3V

–

400KOHM

OUT

400KOHM

OUT

400KOHM

OUT

OUT R

SP211

TTL/CMOS INPUTS

RS-232 OUTPUTS

GND

OUT R

26 27

TTL/CMOS OUTPUTS

RS-232 INPUTS

5KOHM

OUT R

22 23

5KOHM

OUT R

19 18

5KOHM SD

+5V INPUT

400KOHM

OUT

0.1µF

6.3V 0.1µF

6.3V

0.1µF

16V

0.1µF

16V

0.1µF

6.3V

–

400KOHM

OUT

400KOHM

OUT

400KOHM

OUT

OUT* R

IN*

SP211B

TTL/CMOS INPUTS

RS-232 OUTPUTS

GND

OUT* R

IN*

OUT* R

IN*

26 27

TTL/CMOS OUTPUTS

RS-232 INPUTS

5KOHM

OUT* R

IN*

22 23

5KOHM

OUT* R

IN*

19 18

5KOHM SD

*Receivers active during shutdown

PACKAGE: PLASTIC SHRINK

SMALL OUTLINE

(SSOP)

DIMENSIONS (Inches)

Minimum/Maximum

(mm) 24–PIN

28–PIN

0.068/0.078

(1.73/1.99)

0.002/0.008

(0.05/0.21)

0.010/0.015

(0.25/0.38)

0.397/0.407

(10.07/10.33)

0.205/0.212

(5.20/5.38)

0.0256 BSC

(0.65 BSC)

0.301/0.311

(7.65/7.90)

0.022/0.037

(0.55/0.95)

0°/8°

(0°/8°)

0.068/0.078

(1.73/1.99)

0.002/0.008

(0.05/0.21)

0.010/0.015

(0.25/0.38)

0.317/0.328

(8.07/8.33)

0.205/0.212

(5.20/5.38)

0.0256 BSC

(0.65 BSC)

0.301/0.311

(7.65/7.90)

0.022/0.037

(0.55/0.95)

0°/8°

(0°/8°)

PACKAGE: PLASTIC

SMALL OUTLINE (SOIC)

(WIDE)

DIMENSIONS (Inches)

Minimum/Maximum

(mm) 14–PIN

16–PIN

0.093/0.104

(2.352/2.649)

0.004/0.012

(0.102/0.300)

0.013/0.020

(0.330/0.508)

0.398/0.413

(10.10/10.49)

0.291/0.299

(7.402/7.600)

0.050 BSC

(1.270 BSC)

0.394/0.419

(10.00/10.64)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

18–PIN

0.093/0.104

(2.352/2.649)

0.004/0.012

(0.102/0.300)

0.013/0.020

(0.330/0.508)

0.447/0.463

(11.35/11.74)

0.291/0.299

(7.402/7.600)

0.050 BSC

(1.270 BSC)

0.394/0.419

(10.00/10.64)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

20–PIN

0.093/0.104

(2.352/2.649)

0.004/0.012

(0.102/0.300)

0.013/0.020

(0.330/0.508)

0.496/0.512

(12.60/13.00)

0.291/0.299

(7.402/7.600)

0.050 BSC

(1.270 BSC))

0.394/0.419

(10.00/10.64)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

24–PIN

0.093/0.104

(2.352/2.649)

0.004/0.012

(0.102/0.300)

0.013/0.020

(0.330/0.508)

0.599/0.614

(15.20/15.59)

0.291/0.299

(7.402/7.600)

0.050 BSC

(1.270 BSC)

0.394/0.419

(10.00/10.64)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

28–PIN

0.093/0.104

(2.352/2.649)

0.004/0.012

(0.102/0.300)

0.013/0.020

(0.330/0.508)

0.697/0.713

(17.70/18.09)

0.291/0.299

(7.402/7.600)

0.050 BSC

(1.270 BSC)

0.394/0.419

(10.00/10.64)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

0.093/0.104

(2.352/2.649)

0.004/0.012

(0.102/0.300)

0.013/0.020

(0.330/0.508)

0.348/0.363

(8.83/9.22)

0.291/0.299

(7.402/7.600)

0.050 BSC

(1.270 BSC)

0.394/0.419

(10.00/10.64)

0.016/0.050

(0.406/1.270)

0°/8°

(0°/8°)

ALTERNATE

END PINS

(BOTH ENDS)

D1 = 0.005" min.

(0.127 min.)

PACKAGE: PLASTIC

DUAL–IN–LINE

(NARROW)

DIMENSIONS (Inches)

Minimum/Maximum

(mm)

A = 0.210" max.

(5.334 max).

LA2

A1 = 0.015" min.

(0.381min.)

e = 0.100 BSC

(2.540 BSC) e

= 0.300 BSC

(7.620 BSC)

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.735/0.775

(18.669/19.685)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.355/0.400

(9.017/10.160)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

22–PIN8–PIN 14–PIN 16–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

1.145/1.155

(29.083/29.337)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.780/0.800

(19.812/20.320)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

18–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.880/0.920

(22.352/23.368)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

20–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

0.980/1.060

(24.892/26.924)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

ALTERNATE

END PINS

(BOTH ENDS)

D1 = 0.005" min.

(0.127 min.)

PACKAGE: PLASTIC

DUAL–IN–LINE

(NARROW)

DIMENSIONS (Inches)

Minimum/Maximum

(mm)

A = 0.210" max.

(5.334 max).

LA2

A1 = 0.015" min.

(0.381min.)

e = 0.100 BSC

(2.540 BSC) e

= 0.300 BSC

(7.620 BSC)

24–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

1.230/1.280

(31.24/32.51)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

28–PIN

0.115/0.195

(2.921/4.953)

0.014/0.022

(0.356/0.559)

0.045/0.070

(1.143/1.778)

0.008/0.014

(0.203/0.356)

1.385/1.405

(35.179/35.687)

0.300/0.325

(7.620/8.255)

0.240/0.280

(6.096/7.112)

0.115/0.150

(2.921/3.810)

0°/ 15°

(0°/15°)

Now available in Lead Free. To order ad "-L" to the part number.

Example: SP488/TR= Normal, SP488TR-L = Lead Free

ORDERING INFORMATION

RS232 Transceivers:

Model .......... Drivers ............... Receivers..................... Temperature Range ................. Package Type

SP207HCA ....... 5.............................3 ................................ 0°C to +70°C.............................. 24–pin SSOP

SP207HCP ....... 5.............................3 ................................ 0°C to +70°C...................... 24–pin Plastic DIP

SP207HCT ....... 5.............................3 ................................ 0°C to +70°C............................... 24–pin SOIC

SP207HEA ....... 5.............................3 ............................ –40°C to +85 °C..............................24–pin SSOP

SP207HEP ....... 5.............................3 ............................ –40°C to +85 °C...................... 24–pin Plastic DIP

SP207HET........ 5.............................3 ............................ –40°C to +85 °C............................... 24–pin SOIC

RS232 Transceivers with Low–Power Shutdown and Tri–state Enable:

Model .......... Drivers ............... Receivers..................... Temperature Range ................. Package Type

SP211HCA ....... 4.............................5 ................................ 0°C to +70°C.............................. 28–pin SSOP

SP211HCT ....... 4.............................5 ................................ 0°C to +70°C............................... 28–pin SOIC

SP211HEA ....... 4.............................5 ............................ –40°C to +85 °C..............................28–pin SSOP

SP211HET........ 4.............................5 ............................ –40°C to +85 °C............................... 28–pin SOIC

RS232 Transceivers with Low–Power Shutdown, Tri–state Enable, and

Wake–Up Function:

Model .......... Drivers ............... Receivers..................... Temperature Range ................. Package Type

SP207HBCA .... 5....... 3, with 3 active in Shutdown .......... 0°C to +70°C..............................28–pin SSOP

SP207HBCT..... 5....... 3, with 3 active in Shutdown .......... 0°C to +70°C............................... 28–pin SOIC

SP207HBEA..... 5....... 3, with 3 active in Shutdown ...... –40°C to +85°C..............................28–pin SSOP

SP207HBET ..... 5....... 3, with 3 active in Shutdown ...... –40°C to +85°C............................... 28–pin SOIC

SP211HBCA .... 4....... 5, with 5 active in Shutdown .......... 0°C to +70°C..............................28–pin SSOP

SP211HBCT..... 4....... 5, with 5 active in Shutdown .......... 0°C to +70°C............................... 28–pin SOIC

SP211HBEA..... 4....... 5, with 5 active in Shutdown ...... –40°C to +85°C..............................28–pin SSOP

SP211HBET ..... 4....... 5, with 5 active in Shutdown ...... –40°C to +85°C............................... 28–pin SOIC

Corporation

SIGNAL PROCESSING EXCELLENCE

Sipex Corporation reserves the right to make changes to any products described herein. Sipex does not assume any liability arising out of the

application or use of any product or circuit described hereing; neither does it convey any license under its patent rights nor the rights of others.

Sipex Corporation

Headquarters and

Sales Office

22 Linnell Circle

Billerica, MA 01821

TEL: (978) 667-8700

FAX: (978) 670-9001

e-mail: sales@sipex.com

Sales Office

233 South Hillview Drive

Milpitas, CA 95035

TEL: (408) 934-7500

FAX: (408) 935-7600