SP202EEN-L - Sipex Corporation

SP202E/232E/233E/310E/312E

■Operates from Single +5V Power Supply

■Meets All RS-232D and ITU V.28

Specifications

■Operates with 0.1µF to 10µF Capacitors

■High Data Rate – 120Kbps Under Load

■Low Power Shutdown ≤1µA (Typical)

■3-State TTL/CMOS Receiver Outputs

■Low Power CMOS – 3mA Operation

■Improved ESD Specifications:

±15kV Human Body Model

±15kV IEC1000-4-2 Air Discharge

±8kV IEC1000-4-2 Contact Discharge

Number of RS232 No. of Receivers No. of External

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

SP202E 22 0 4 NoNoNo

SP232E 22 0 4 NoNoNo

SP233E 22 0 0 NoNoNo

SP310E 22 0 4 Yes No Yes

SP312E 22 2 4 Yes Yes Yes

High-P erf ormance RS-232

Line Drivers/Receivers

DESCRIPTION

SELECTION TABLE

The SP202E/232E/233E/310E/312E devices are a family of line driver and receiver pairs that

meet the specifications of RS-232 and V.28 serial protocols with enhanced ESD performance.

The ESD tolerance has been improved on these devices to over ±15KV for both Human Body

Model and IEC1000-4-2 Air Discharge Method. These devices are pin-to-pin compatible with

Sipex's SP232A/233A/310A/312A devices as well as popular industry standards. As with the

initial versions, the SP202E/232E/233E/310E/312E devices feature at least 120Kbps data rate

under load, 0.1µF charge pump capacitors, and overall ruggedness for commercial applications.

This family also features Sipex's BiCMOS design allowing low power operation without

sacrificing performance. The series is available in plastic DIP and SOIC packages operating over

the commercial and industrial temperature ranges.

GND

OUT

V+

V-

OUT

SP202E

Now Available in Lead Free Packaging

This is a stress rating only and functional operation of the device at

these or any other conditions above those indicated in the operation

sections of this specification is not implied. Exposure to absolute

maximum rating conditions for extended periods of time may affect

reliability.

Vcc ................................................................................................................................................................. +6V

V+.................................................................................................................... (Vcc-0.3V) to +11.0V

V-............................................................................................................................................................ -11.0V

Input Voltages

TIN ......................................................................................................................... -0.3 to (Vcc +0.3V)

RIN ............................................................................................................................................................ ±15V

Output Voltages

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

ROUT ................................................................................................................ -0.3V to (Vcc +0.3V)

Short Circuit Duration

TOUT ......................................................................................................................................... Continuous

VCC=+5V±10%; 0.1µF charge pump capacitors; TMIN to TMAX unless otherwise noted.

PARAMETERS MIN. TYP. MAX. UNITS CONDITIONS

TTL INPUT

Logic Threshold

LOW 0.8 Volts TIN ; EN, SD

HIGH 2.0 Volts TIN ; EN, SD

Logic Pull-Up Current 15 200 µAT

IN = 0V

TTL OUTPUT

TTL/CMOS Output

Voltage, Low 0.4 Volts IOUT = 3.2mA; Vcc = +5V

Voltage, High 3.5 Volts IOUT = -1.0mA

Leakage Current **; TA = +25°0.05 ±10 µAEN = VCC, 0V≤VOUT ≤VCC

RS-232 OUTPUT

Output Voltage Swing ±5±6Volts All transmitter outputs loaded

with 3kΩ to Ground

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

Output Short Circuit Current ±18 mA Infinite duration

Maximum Data Rate 120 240 Kbps CL = 2500pF, RL= 3kΩ

RS-232 INPUT

Voltage Range -15 +15 Volts

Voltage Threshold

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

HIGH 1.7 2.8 Volts VCC = 5V, TA = +25°C

Hysteresis 0.2 0.5 1.0 Volts VCC = 5V, TA = +25°C

Resistance 3 5 7 kΩ

= +25°C, -15V ≤ V

≤ +15V

DYNAMIC CHARACTERISTICS

Driver Propagation Delay 1.5 3.0 µsTTL to RS-232; CL = 50pF

Receiver Propagation Delay 0.1 1.0 µsRS-232 to TTL

Instantaneous Slew Rate 30 V/µsC

L = 10pF, RL= 3-7kΩ;

TA =+25°C

Transition Region Slew Rate 10 V/µsC

L = 2500pF, RL= 3kΩ;

measured from +3V to -3V

or -3V to +3V

Output Enable Time ** 400 ns SP310E and SP312E only

Output Disable Time ** 250 ns SP310E and SP312E only

POWER REQUIREMENTS

VCC Power Supply Current 3 5 mA No load, TA= +25°C; VCC = 5V

15 mA All transmitters RL = 3kΩ;

TA = +25°C

Shutdown Supply Current ** 1 5 µAV

CC = 5V, TA = +25°C

**SP310E and SP312E only

ELECTRICAL CHARACTERISTICS

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

(derate 7mW/°C above +70°C)

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

(derate 7mW/°C above +70°C)

ABSOLUTE MAXIMUM RATINGS

PERFORMANCE CURVES

-55 -40 0 25 70 85 125

Temperature (°C)

= 6V

= 5V

= 4V

= 3V

(mA)

051015 20

Load Current (mA)

V+ (Volts)

= 5V

= 4V

= 6V

25 30 35 40

02468101214

Load Current (mA)

V– Voltage (Volts)

-3

-4

-5

-6

-7

-8

-9

-10

-11

= 6V

= 5V

= 4V

OUT

V-

–

OUT

GND

V+

GND

V–

SP233ECT

20-PIN SOIC

GND

OUT

V+

V-

OUT

SP232E

SHUTDOWN

GND

OUT

EN *

V+

V-

OUT

SP312E

ON/OFF

GND

OUT

V+

V-

OUT

SP310E

GND

OUT

V+

V-

OUT

SP202E

SHDN

GND

T1OUT

R1IN

R1OUT

N.C.

T1IN

T2IN

N.C.

C1+

V+

C1-

C2+

C2-

V-

T2OUT

R2IN

R2OUT

SP310E_A/312E_A

20-PIN SSOP

N.C./EN

* N.C. for SP310E_A, EN for SP312E_A

PINOUTS

4.5 4.75 5.0 5.25 5.5

(Volts)

5.0

6.5

7.0

7.5

8.0

8.5

9.0

Load current = 0mA

= 25°C

(Volts)

5.5

6.0

Figure 1. Typical Circuit using the SP202E or SP232E.

FEATURES…

The SP202E/232E/233E/310E/312E devices

are a family of line driver and receiver pairs that

meet the specifications of RS-232 and V.28

serial protocols with enhanced ESD perfor-

mance. The ESD tolerance has been improved

on these devices to over ±15KV for both Human

Body Model and IEC1000-4-2 Air Discharge

Method. These devices are pin-to-pin compat-

ible with Sipex's 232A/233A/310A/312A

devices as well as popular industry standards.

As with the initial versions, the SP202E/232E/

233E/310E/312E devices feature10V/µs slew

rate, 120Kbps data rate under load, 0.1µF

charge pump capacitors, overall ruggedness

for commercial applications, and increased drive

current for longer and more flexible cable

configurations. This family also features Sipex's

BiCMOS design allowing low power operation

without sacrificing performance.

The SP202E/232E/233E/310E/312E devices

have internal charge pump voltage converters

which allow them to operate from a single +5V

supply. The charge pumps will operate with

polarized or non-polarized capacitors ranging

from 0.1 to 10 µF and will generate the ±6V

needed to generate the RS-232 output levels.

Both meet all EIA RS-232 and ITU V.28

specifications.

The SP310E provides identical features as the

SP232E with a single control line which

simultaneously shuts down the internal DC/DC

converter and puts all transmitter and receiver

outputs into a high impedance state. The SP312E

is identical to the SP310E with separate tri-state

and shutdown control lines.

THEORY OF OPERATION

The SP232E, SP233E, SP310E and SP312E

devices are made up of three basic circuit blocks –

1) a driver/transmitter, 2) a receiver and 3) a charge

pump. Each block is described below.

Driver/Transmitter

The drivers are inverting transmitters, which ac-

cept TTL or CMOS inputs and output the RS-232

signals with an inverted sense relative to the input

logic levels. Typically the RS-232output voltage

swing is ±6V. Even under worst case loading

conditions of 3kOhms and 2500pF, the output is

guaranteed to be ±5V, which is consistent with the

RS-232 standard specifications. The transmitter

outputs are protected against infinite short-circuits

to ground without degradation in reliability.

R INR OUT

12 13 R INR OUT

10 7

T IN

T OUT

11 14

T IN

T OUT

15GND

400k Ω

TTL/CMOS INPUTS

RS-232 OUTPUTS

1C +

C -

V+

0.1 F

6.3V

Charge Pump

+5V INPUT

V-

TTL/CMOS OUTPUTS

RS-232 INPUTS

5kΩ

0.1 F

16V

5kΩ

4C +

C -

0.1 F

16V

0.1 F 6.3V

10 F 6.3V

SP232E

*The negative terminal of the V+ storage capacitor can be tied

to either VCC or GND. Connecting the capacitor to VCC (+5V)

is recommended.

SP202E

The instantaneous slew rate of the transmitter

output is internally limited to a maximum of 30V/

µs in order to meet the standards [EIA RS-232-D

2.1.7, Paragraph (5)]. However, the transition re-

gion slew rate of these enhanced products is typi-

cally 10V/µs. The smooth transition of the loaded

output from VOL to VOH clearly meets the mono-

tonicity requirements of the standard [EIA

RS-232-D 2.1.7, Paragraphs (1) & (2)].

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 virtually immune

to noisy transmission lines.

The input thresholds are 0.8V minimum and 2.4V

maximum, again well within the ±3V RS-232

requirements. The receiver inputs are also pro-

tected against voltages up to ±15V. Should an

input be left unconnected, a 5KOhm pulldown

resistor to ground will commit the output of the

receiver to a high state.

20 19 R INR OUT

R INR OUT

118

T IN

T OUT

T IN

T OUT

GND

400k Ω

TTL/CMOS INPUTS

RS-232 OUTPUTS

13 C +

C -

V-

V+

+5V INPUT

TTL/CMOS OUTPUTS

RS-232 INPUTS

5kΩ

10 C +

C +

C -

GND

Do not make

connection to

these pins

Internal

-10V Power

Supply

Internal

+10V Power

Supply

SP233ECT

Figure 2. Typical Circuits using the SP233ECP and SP233ECT

Figure 3. Typical Circuits using the SP310E and SP312E

10 9 R INR OUT

13 14 R INR OUT

11 8

T IN

T OUT

12 15

T IN

T OUT

16GND

400k Ω

TTL/CMOS INPUTS

RS-232 OUTPUTS

2C +

C -

V+

0.1 F

6.3V

Charge Pump

+5V INPUT

V-

TTL/CMOS OUTPUTS

RS-232 INPUTS

5kΩ

5C +

C -

0.1 F

16V

10 F 6.3V

SP310E

18 ON/OFF

0.1 µF

16V

*The negative terminal of the V+ storage capacitor can be tied

to either V

or GND. Connecting the capacitor to V

(+5V)

is recommended.

0.1 µF

16V

10 9R INR OUT

13 14 R INR OUT

11 8

T IN

T OUT

12 15

T IN

T OUT

16GND

400k Ω

TTL/CMOS INPUTS

RS-232 OUTPUTS

2C +

C -

V+

0.1 F

6.3V

+5V INPUT

V-

TTL/CMOS OUTPUTS

RS-232 INPUTS

5kΩ

0.1 F

16V

5kΩ

5C +

C -

0.1 F

16V

Charge Pump

10 F 6.3V

SP312E

18 SHUTDOWN

0.1 F

16V

*The negative terminal of the V+ storage capacitor can be tied

to either V

or GND. Connecting the capacitor to V

(+5V)

is recommended.

VCC = +5V

–5V –5V

+5V

VSS Storage Capacitor

VDD Storage Capacitor

C1C2

–

––

Figure 4. Charge Pump — Phase 1

Figure 5. Charge Pump — Phase 2

VCC = +5V

–10V

VSS Storage Capacitor

VDD Storage Capacitor

C1C2

–

––

In actual system applications, it is quite possible

for signals to be applied to the receiver inputs

before power is applied to the receiver circuitry.

This occurs, for example, when a PC user attempts

to print, only to realize the printer wasn’t turned on.

In this case an RS-232 signal from the PC will

appear on the receiver input at the printer. When

the printer power is turned on, the receiver will

operate normally. All of these enhanced devices

are fully protected.

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 power supplies. 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

Figure 6. Charge Pump Waveforms

+10V

a) C2+

GND

b) C2–

–10V

Figure 7. Charge Pump — Phase 3

= +5V

–5V

+5V

–5V

Storage Capacitor

–

––

Figure 8. Charge Pump — Phase 4

= +5V

+10V

Storage Capacitor

–

––

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.

Shutdown (SD) and Enable (EN) for the

SP310E and SP312E

Both the SP310E and SP312E have a shutdown/

standby mode to conserve power in battery-pow-

ered systems. To activate the shutdown mode,

which stops the operation of the charge pump, a

logic “0” is applied to the appropriate control line.

For the SP310E, this control line is ON/OFF (pin

18). Activating the shutdown mode also puts the

Table 1. Wake-up Function Truth Table.

SD EN Power

Up/Down Receiver

Outputs

Down

Enable

Tri–state

Enable

Tri–state

SP310E transmitter and receiver outputs in a high

impedance condition (tri-stated). The shutdown

mode is controlled on the SP312E by a logic “0”

on the SHUTDOWN control line (pin 18); this also

puts the transmitter outputs in a tri–state mode.

The receiver outputs can be tri–stated separately

during normal operation or shutdown by a logic

“1” on the ENABLE line (pin 1).

Wake–Up Feature for the SP312E

The SP312E has a wake–up feature that keeps

all the receivers in an enabled state when the

device is in the shutdown mode. Table 1 defines

the truth table for the wake–up function.

With only the receivers activated, the SP312E

typically draws less than 5µA supply current.

In the case of a modem interfaced to a computer

in power down mode, the Ring Indicator (RI)

signal from the modem would be used to "wake

up" the computer, allowing it to accept data

transmission.

After the ring indicator signal has propagated

through the SP312E receiver, it can be used to

trigger the power management circuitry of the

computer to power up the microprocessor, and

bring the SD pin of the SP312E to a logic high,

taking it out of the shutdown mode. The receiver

propagation delay is typically 1µs. The enable

time for V+ and V– is typically 2ms. After V+ and

V– have settled to their final values, a signal can

be sent back to the modem on the data terminal

ready (DTR) pin signifying that the computer is

ready to accept and transmit data.

Pin Strapping for the SP233ECT

The SP233E packaged in the 20–pin SOIC pack-

age (SP233ECT) has a slightly different pinout

than the SP233E in other package configurations.

To operate properly, the following pairs of pins

must be externally wired together:

the two V– pins (pins 10 and 17)

the two C2+ pins (pins 12 and 15)

the two C2– pins (pins 11 and 16)

All other connections, features, functions and

performance are identical to the SP233E as

specified elsewhere in this data sheet.

ESD TOLERANCE

The SP202E/232E/233E/310E/312E devices

incorporates ruggedized ESD cells on all driver

output and receiver input pins. The ESD struc-

ture is improved over our previous family for

more rugged applications and environments sen-

sitive to electro-static discharges and associated

transients. The improved ESD tolerance is at

least ±15KV without damage nor latch-up.

There are different methods of ESD testing

applied: a) MIL-STD-883, Method 3015.7

b) IEC1000-4-2 Air-Discharge

c) IEC1000-4-2 Direct Contact

The Human Body Model has been the generally

accepted ESD testing method for semiconductors.

This method is also specified in MIL-STD-883,

Method 3015.7 for ESD testing. The premise of

this ESD test is to simulate the human body’s

potential to store electro-static energy and

discharge it to an integrated circuit. The

simulation is performed by using a test model as

shown in Figure 9. This method will test the IC’s

capability to withstand an ESD transient during

normal handling such as in manufacturing areas

where the ICs tend to be handled frequently.

The IEC-1000-4-2, formerly IEC801-2, is

generally used for testing ESD on equipment and

systems. For system manufacturers, they must

guarantee a certain amount of ESD protection

since the system itself is exposed to the outside

environment and human presence. The premise

SW1 SW2

Device

Under

Test

DC Power

Source

SW1 SW2

Figure 9. ESD Test Circuit for Human Body Model

and

add up to 330Ω for IEC1000-4-2.

and

add up to 330Ω for IEC1000-4-2.

Contact-Discharge Module

SW1 SW2

Device

Under

Test

DC Power

Source

SW1 SW2

Contact-Discharge Module

Figure 10. ESD Test Circuit for IEC1000-4-2

with IEC1000-4-2 is that the system is required

to withstand an amount of static electricity when

ESD is applied to points and surfaces of the

equipment that are accessible to personnel during

normal usage. The transceiver IC receives most

of the ESD current when the ESD source is

applied to the connector pins. The test circuit for

IEC1000-4-2 is shown on Figure 10. There are

two methods within IEC1000-4-2, the Air

Discharge method and the Contact Discharge

method.

With the Air Discharge Method, an ESD voltage

is applied to the equipment under test (EUT)

through air. This simulates an electrically charged

person ready to connect a cable onto the rear of

the system only to find an unpleasant zap just

before the person touches the back panel. The

high energy potential on the person discharges

through an arcing path to the rear panel of the

system before he or she even touches the system.

This energy, whether discharged directly or

through air, is predominantly a function of the

SP202E HUMAN BODY IEC1000-4-2

Family MODEL Air Discharge Direct Contact Level

Driver Outputs ±15kV ±15kV ±8kV 4

Receiver Inputs ±15kV ±15kV ±8kV 4

Figure 11. ESD Test Waveform for IEC1000-4-2

t=0ns t=30ns

15A

30A

t ➙

i ➙

Table 2. Transceiver ESD Tolerance Levels

discharge current rather than the discharge

voltage. Variables with an air discharge such as

approach speed of the object carrying the ESD

potential to the system and humidity will tend to

change the discharge current. For example, the

rise time of the discharge current varies with the

approach speed.

The Contact Discharge Method applies the ESD

current directly to the EUT. This method was

devised to reduce the unpredictability of the

ESD arc. The discharge current rise time is

constant since the energy is directly transferred

without the air-gap arc. In situations such as

hand held systems, the ESD charge can be directly

discharged to the equipment from a person already

holding the equipment. The current is transferred

on to the keypad or the serial port of the equipment

directly and then travels through the PCB and

finally to the IC.

The circuit models in Figures 9 and 10 represent

the typical ESD testing circuit used for all three

methods. The CS is initially charged with the DC

power supply when the first switch (SW1) is on.

Now that the capacitor is charged, the second

switch (SW2) is on while SW1 switches off. The

voltage stored in the capacitor is then applied

through RS, the current limiting resistor, onto the

device under test (DUT). In ESD tests, the SW2

switch is pulsed so that the device under test

receives a duration of voltage.

For the Human Body Model, the current limiting

resistor (RS) and the source capacitor (CS) are

1.5kΩ an 100pF, respectively. For IEC-1000-4-

2, the current limiting resistor (RS) and the source

capacitor (CS) are 330Ω an 150pF, respectively.

The higher CS value and lower RS value in the

IEC1000-4-2 model are more stringent than the

Human Body Model. The larger storage capacitor

injects a higher voltage to the test point when

SW2 is switched on. The lower current limiting

resistor increases the current charge onto the test

point.

E1 E

INDEX AREA

2x2

Seating Plane

A2 A

SEE DETAIL “A”

(b)

WITH LEAD FINISH

BASE METAL

Seaing Plane

2 NX R R1

DETAIL A

- - 2.0

0.05 - -

Dimensions in (mm)

20 PIN SSOP

JEDEC MO-150

(AE) Variation

1.65 1.75 1.85

0.22 - 0.38

0.09 - 0.25

0.55 0.75 0.95

0º 4º 8º

MIN NOM MAX

7.40 7.80 8.20

5.00 5.30 5.60

1.25 REF

6.90 7.20 7.50

Section A-A

20 PIN SSOP

PACKAGE: 20 PIN SSOP

Ø1

1.65

TOP VIEW

SECTION B-B

16 PIN NSOIC

WITH PLATING

BASE METAL

DIMENSIONS

(mm)

16 Pin NSOIC

(JEDEC MS-012,

AC - VARIATION)

1.35

0.40

0.31 0.51

SYMBOL MIN NOM MAX

0.10 - 0.25

1.75

1.25

0.17 0.25

6.00 BSC

3.90 BSC

1.27 BSC1.27

1.04 REF

0.25 BSC

0º

5º 8º

15º

Ø1

Seating Plane

Gauge Plane

VIEW C

AA2

SIDE VIEW

E/2

INDEX AREA

(D/2 X E1/2)

E1/2

SEE VIEW C

Seating Plane

D9.90 BSC

PACKAGE: 16 PIN NSOIC

Ø1

2.55

TOP VIEW

16 PIN SOIC WIDE

WITH PLATING

BASE METAL

DIMENSIONS IN

(mm)

16 Pin SOIC (WIDE)

(JEDEC MS-013,

AA - VARIATION)

2.35

10.30 BSC

0.40

0.31 0.51

SYMBOL MIN NOM MAX

0.10 - 0.30

2.65

2.05

0.20 0.33

10.30 BSC

7.50 BSC

1.27 BSC1.27

1.40 REF

0.25 BSC

0º

5º 8º

15º

Ø1

Seating Plane

Gauge Plane

VIEW C

AA2

SIDE VIEW

E/2

INDEX AREA

(D/2 X E1/2)

E1/2

SEE VIEW C

123

SECTION B-B

Seating Plane

PACKAGE: 16 PIN WSOIC

123

INDEX

AREA

- - .210

.015 -

Dimensions in inches

18 PIN PDIP

JEDEC MS-001

(AC) Variation

.115 .130 .195

.014 .018 .022

.045 .060 .070

.240 .250 .280

.115 .130 .150

MIN NOM MAX

b3 .030 .039 .045

.008

.010 .014

.880 .900 .920

.005

.300 .310 .325

.100 BSC

.300 BSC

.430

N/2

18 pin PDIP

LA2

PACKAGE: 18 PIN PDIP

Part Number Temperature Range Topmark Package

SP202ECN.............................0°C to +70°C.................................SP202ECN........................................................................16–pin NSOIC

SP202ECN/TR.......................0°C to +70°C.................................SP202ECN........................................................................16–pin NSOIC

SP202ECP.............................0°C to +70°C.................................SP202ECP.........................................................................16–pin PDIP

SP202ECT.............................0°C to +70°C.................................SP202ECT.........................................................................16–pin WSOIC

SP202ECT/TR.......................0°C to +70°C.................................SP202ECT.........................................................................16–pin WSOIC

SP202EEN..........................–40°C to +85°C................................SP202EEN.........................................................................16–pin NSOIC

SP202EEN/TR....................–40°C to +85°C................................SP202EEN.........................................................................16–pin NSOIC

SP202EEP..........................–40°C to +85°C................................SP202EEP.........................................................................16–pin PDIP

SP202EET..........................–40°C to +85°C................................SP202EET..........................................................................16–pin WSOIC

SP202EET/TR.....................–40°C to +85°C................................SP202EET..........................................................................16–pin WSOIC

SP232ECN.............................0°C to +70°C................................SP232ECN..........................................................................16–pin NSOIC

SP232ECN/TR.......................0°C to +70°C................................SP232ECN..........................................................................16–pin NSOIC

SP232ECP.............................0°C to +70°C.................................SP232ECP.........................................................................16–pin PDIP

SP232ECT.............................0°C to +70°C.................................SP232ECT..........................................................................16–pin WSOIC

SP232ECT/TR.......................0°C to +70°C.................................SP232ECT..........................................................................16–pin WSOIC

SP232EEN..........................–40°C to +85°C................................SP232EEN..........................................................................16–pin NSOIC

SP232EEN/TR....................–40°C to +85°C................................SP232EEN..........................................................................16–pin NSOIC

SP232EEP..........................–40°C to +85°C................................SP232EEP..........................................................................16–pin PDIP

SP232EET..........................–40°C to +85°C................................SP232EET...........................................................................16–pin WSOIC

SP232EET/TR.....................–40°C to +85°C................................SP232EET...........................................................................16–pin WSOIC

SP233ECT............................0°C to +70°C.................................SP233ECT...........................................................................20–pin WSOIC

SP233ECT/TR......................0°C to +70°C.................................SP233ECT...........................................................................20–pin WSOIC

SP233EET..........................–40°C to +85°C................................SP233EET...........................................................................20–pin WSOIC

SP233EET/TR.....................–40°C to +85°C................................SP233EET...........................................................................20–pin WSOIC

SP310ECP............................0°C to +70°C.................................SP310ECP.........................................................................18–pin PDIP

SP310ECT............................0°C to +70°C.................................SP310ECT..........................................................................18–pin WSOIC

SP310ECT/TR......................0°C to +70°C.................................SP310ECT..........................................................................18–pin WSOIC

SP310ECA............................0°C to +70°C.................................SP310ECA..........................................................................20–pin SSOP

SP310ECA/TR......................0°C to +70°C.................................SP310ECA..........................................................................20–pin SSOP

SP310EEP..........................–40°C to +85°C................................SP310EEP..........................................................................18–pin PDIP

SP310EET..........................–40°C to +85°C................................SP310EET...........................................................................18–pin WSOIC

SP310EET/TR.....................–40°C to +85°C................................SP310EET...........................................................................18–pin WSOIC

SP310EEA..........................–40°C to +85°C................................SP310EEA...........................................................................20–pin SSOP

SP310EEA/TR.....................–40°C to +85°C................................SP310EEA...........................................................................20–pin SSOP

SP312ECP............................0°C to +70°C.................................SP312ECP..........................................................................18–pin PDIP

SP312ECT............................0°C to +70°C.................................SP312ECT...........................................................................18–pin WSOIC

SP312ECT/TR......................0°C to +70°C.................................SP312ECT...........................................................................18–pin WSOIC

SP312ECA............................0°C to +70°C.................................SP312ECA...........................................................................20–pin SSOP

SP312ECA/TR......................0°C to +70°C.................................SP312ECA...........................................................................20–pin SSOP

SP312EEP..........................–40°C to +85°C................................SP312EEP...........................................................................18–pin PDIP

SP312EET..........................–40°C to +85°C................................SP312EET............................................................................18–pin WSOIC

SP312EET/TR.....................–40°C to +85°C................................SP312EET............................................................................18–pin WSOIC

SP312EEA..........................–40°C to +85°C................................SP312EEA............................................................................20–pin SSOP

SP312EEA/TR.....................–40°C to +85°C................................SP312EEA............................................................................20–pin SSOP

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.

Available in lead free packaging. To order add "-L" suffix to part number.

Example: SP312EEA/TR = standard; SP312EEA-L/TR = lead free

/TR = Tape and Reel

Pack quantity is 1,500 for SSOP or WSOIC and 2,500 for NSOIC.

Sipex Corporation

Headquarters and

Sales Office

233 South Hillview Drive

Milpitas, CA 95035

TEL: (408) 934-7500

FAX: (408) 935-7600

ORDERING INFORMATION

DATE REVISION DESCRIPTION

6/2/04 A Incorporated new package drawings with JEDEC reference.

7/19/04 A Added typical output voltage swing value (±6V).

REVISION HISTORY