SP3223EBCY-L/TR - Sipex Corporation

SP3223EB/3243EB

Intelligent +3.0V to +5.5V RS-232 Transceivers

The SP3223EB and SP3243EB products are RS-232 transceiver solutions intended for

portable or hand-held applications such as notebook and palmtop computers. The SP3223EB

and SP3243EB use an internal high-efficiency, charge-pump power supply that requires only

0.1µF capacitors in 3.3V operation. This charge pump and Sipex's driver architecture allow

the SP3223EB/3243EB series to deliver compliant RS-232 performance from a single power

supply ranging from +3.0V to +5.5V. The SP3223EB is a 2-driver/2-receiver device, and the

SP3243EB is a 3-driver/5-receiver device ideal for laptop/notebook computer and PDA

applications. The SP3243EB includes one complementary receiver that remains alert to

monitor an external device's Ring Indicate signal while the device is shutdown.

The AUTO ON-LINE® feature allows the device to automatically "wake-up" during a shutdown

state when an RS-232 cable is connected and a connected peripheral is turned on. Otherwise,

the device automatically shuts itself down drawing less than 1µA.

■ Meets true EIA/TIA-232-F Standards

from a +3.0V to +5.5V power supply

■ Interoperable with EIA/TIA-232 and

adheres to EIA/TIA-562 down to a +2.7V

power source

■ AUTO ON-LINE® circuitry automatically

wakes up from a 1µA shutdown

■ Minimum 250kbps data rate under load

■ Regulated Charge Pump Yields Stable

RS-232 Outputs Regardless of VCC

Variations

■ Enhanced ESD Specifications:

+15kV Human Body Model

+15kV IEC1000-4-2 Air Discharge

+8kV IEC1000-4-2 Contact Discharge

DESCRIPTION

SELECTION TABLE

Applicable U.S. Patents - 5,306,954; and other patents pending.

eciveDseilppuSrewoP232-SR

srevirD

232-SR

srevieceR

lanretxE

stnenopmoC

ENIL-NOOTUA

yrtiucriC

etatS-3LTTfo.oN

sniP

BE3223PSV5.5+otV0.3+22sroticapac4SEYSEY02

BE3423PSV5.5+otV0.3+35sroticapac4SEYSEY82

V-

417

SHUTDOWN

C1+

V+

C1-

C2+

C2-

ONLINE

GND

OUT

STATUS

10 11

OUT

SP3223EB

OUT T

OUT

Now Available in Lead Free Packaging

PARAMETER MIN. TYP. MAX. UNITS CONDITIONS

DC CHARACTERISTICS

Supply Current, 1.0 10 µAAll RxIN open, ONLINE = GND,

AUTO ON-LINE®SHUTDOWN = VCC, TxIN = VCC or

GND,VCC = +3.3V, TAMB = +25°C

Supply Current, Shutdown 1.0 10 µASHUTDOWN = GND,

VCC = +3.3V, TAMB = +25°C,

TxIN = VCC or GND

Supply Current, 0.3 1.0 mA ONLINE = SHUTDOWN = VCC,

AUTO ON-LINE® Disabled TxIN = VCC or GND,

no load, VCC = +3.3V, TAMB = +25°C

LOGIC INPUTS AND RECEIVER OUTPUTS

Input Logic Threshold VCC = +3.3V or +5.0V, TxIN,

LOW GND 0.8 V EN (SP3223EB), ONLINE,

HIGH 2.4 VCC V SHUTDOWN

Input Leakage Current ±0.01 ±1.0 µATxIN, EN (SP3223EB), ONLINE,

SHUTDOWN,

TAMB = +25°C, VIN = 0V to VCC

Output Leakage Current ±0.05 ±10 µAReceivers disabled, VOUT = 0V to

VCC

Output Voltage LOW 0.4 V IOUT = 1.6mA

Output Voltage HIGH VCC - 0.6 VCC - 0.1 V IOUT = -1.0mA

DRIVER OUTPUTS

Output Voltage Swing ±5.0 ±5.4 V All driver outputs loaded with 3KΩ

to GND, TAMB = +25°C

Output Resistance 300 ΩVCC = V+ = V- = 0V, VOUT = ±2V

Output Short-Circuit Current ±35 ±60 mA VOUT = 0V

Output Leakage Current ±25 µAV

CC = 0V or 3.0V to 5.5V,

VOUT = ±12V, Drivers disabled

NOTE 1: V+ and V- can have maximum magnitudes of 7V, but their absolute difference cannot exceed 13V.

ABSOLUTE MAXIMUM RATINGS

These are stress ratings only and functional operation

of the device at these ratings 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 and cause permanent damage to the

device.

VCC ...................................................... -0.3V to +6.0V

V+ (NOTE 1) ...................................... -0.3V to +7.0V

V- (NOTE 1) ....................................... +0.3V to -7.0V

V+ + |V-| (NOTE 1) ........................................... +13V

ICC (DC VCC or GND current) ......................... +100mA

Input Voltages

TxIN, ONLINE,

SHUTDOWN, EN (SP3223E)............ -0.3V to +6.0V

RxIN .................................................................. +25V

Output Voltages

TxOUT ........................................................... +13.2V

RxOUT, STATUS ..................... -0.3V to (VCC + 0.3V)

Unless otherwise noted, the following specifications apply for VCC = +3.0V to +5.5V with TAMB = TMIN to TMAX,

C1 - 4 = 0.1µF. Typical values apply at VCC = +3.3V or +5.0V and TAMB = 25°C.

ELECTRICAL CHARACTERISTICS

Short-Circuit Duration

TxOUT .................................................... Continuous

Storage Temperature ...................... -65°C to +150°C

Power Dissipation per package

28-pin PDIP

(derate 16.0mW/°C above+70°C) ...................... 1300mW

20-pin SSOP

(derate 9.25mW/°C above +70°C) ...................... 750mW

20-pin TSSOP

(derate 11.1mW/°C above +70°C) ....................... 900mW

28-pin SOIC

(derate 12.7mW/°C above +70°C) .................... 1000mW

28-pin SSOP

(derate 11.2mW/°C above +70°C) ...................... 900mW

28-pin TSSOP

(derate 11.1mW/°C above +70°C) ....................... 900mW

32-pin QFN

ELECTRICAL CHARACTERISTICS

Unless otherwise noted, the following specifications apply for VCC = +3.0V to +5.5V with TAMB = TMIN to TMAX,

C1 - 4 = 0.1µF. Typical values apply at VCC = +3.3V or +5.0V and TAMB = 25°C.

PARAMETER MIN. TYP. MAX. UNITS CONDITIONS

RECEIVER INPUTS

Input Voltage Range -25 25 V

Input Threshold LOW 0.6 1.2 V VCC = 3.3V

Input Threshold LOW 0.8 1.5 V VCC = 5.0V

Input Threshold HIGH 1.5 2.4 V VCC = 3.3V

Input Threshold HIGH 1.8 2.4 V VCC = 5.0V

Input Hysteresis 0.3 V

Input Resistance 3 5 7 kΩ

AUTO ON-LINE® CIRCUITRY CHARACTERISTICS (ONLINE = GND, SHUTDOWN = VCC)

STATUS Output Voltage LOW 0.4 V IOUT = 1.6mA

STATUS Output Voltage HIGH VCC - 0.6 V IOUT = -1.0mA

Receiver Threshold to Drivers

Enabled (tONLINE)200 µsFigure 20

Receiver Positive or Negative 0.5 µsFigure 20

Threshold to STATUS HIGH

(tSTSH)

Receiver Positive or Negative 20 µsFigure 20

Threshold to STATUS LOW

(tSTSL)

TIMING CHARACTERISTICS

Maximum Data Rate 250 kbps RL = 3KΩ, CL = 1000pF,

one driver active

Receiver Propagation Delay

tPHL 0.15 µsReceiver input to Receiver output,

tPLH 0.15 CL = 150pF

Receiver Output Enable Time 200 ns Normal operation

Receiver Output Disable Time 200 ns Normal operation

Driver Skew 100 ns | tPHL - tPLH |, TAMB = 25°C

Receiver Skew 50 ns | tPHL - tPLH |

Transition-Region Slew Rate 30 V/µsV

CC= 3.3V, RL = 3KΩ, TAMB = 25°C,

measurements taken from -3.0V to

+3.0V or +3.0V to -3.0V

Figure 1. Transmitter Output Voltage VS. Load

Capacitance for the SP3223EB

Figure 2. Slew Rate VS. Load Capacitance for the

SP3223EB

TYPICAL PERFORMANCE CHARACTERISTICS

Unless otherwise noted, the following performance characteristics apply for VCC = +3.3V, 250kbps data rate, all drivers

loaded with 3KΩ, 0.1µF charge pump capacitors, and TAMB = +25°C.

00 500 1000 2000 3000 4000 5000

Slew rate (V/µs)

Load Capacitance (pF)

- Slew

+ Slew

1 Transmitter at 250Kbps

1 Transmitter at 15.6Kbps

All drivers loaded 3K + Load Cap

ICC (mA)

Load Capacitance (pF)

01000 2000 3000 4000 5000

250Kbps

125Kbps

20Kbps

1 Transmitter at 250Kbps

1 Transmitter at 15.6Kbps

All drivers loaded 3K + Load Cap

Figure 3. Supply Current VS. Load Capacitance when

Transmitting Data for the SP3223EB

Figure 4. Supply Current VS. Supply Voltage for

the SP3243EB

02.7 3 3.5 4 4.5 5

Supply Voltage (V

)

Supply Current (mA)

1 Transmitter at 250Kbps

2 Transmitters at 15.6Kbps

All drivers loaded with 3K // 1000pF

Figure 5. Transmitter Output Voltage VS. Supply

Voltage for the SP3243EB

Figure 6. Transmitter Output Voltage VS. Load

Capacitance for the SP3243EB

-2

-4

-6 0 1000 2000 3000 4000 5000

TxOUT +

TxOUT -

Transmitter Output

Voltage (V

)

Load Capacitance (pF)

-2

-4

-6 0 1000 2000 3000 4000 5000

TxOUT +

TxOUT -

Transmitter Output

Voltage (V)

Load Capacitance (pF)

-2

-4

-6 2.7 3 3.5 4 4.5 5

Supply Voltage (V

)

Transmitter Output

Voltage (V

)

TxOUT -

TxOUT +

TYPICAL PERFORMANCE CHARACTERISTICS

Unless otherwise noted, the following performance characteristics apply for VCC = +3.3V, 250kbps data rate, all drivers

loaded with 3KΩ, 0.1µF charge pump capacitors, and TAMB = +25°C.

Figure 7. Slew Rate VS. Load Capacitance for the

SP3243EB

00500 1000 2000 3000 4000 5000

Slew rate (V/µs)

Load Capacitance (pF)

- Slew

+ Slew

1 Transmitter at 250Kbps

2 Transmitter at 15.6Kbps

All drivers loaded 3K + Load Cap

Figure 8. Supply Current VS. Load Capacitance when

Transmitting Data for the SP3243EB

Supply Current (mA)

Load Capacitance (pF)

0 1000 2000 3000 4000 5000

250Kbps 120Kbps

20Kbps

1 Transmitter at full Data Rate

2 Transmitters at 15.5 Kbps

All Transmitters loades 3K + Load Cap

-2

-4

-6 2.7 3 3.5 4 4.5 5

Supply Voltage (V

)

Transmitter Output

Voltage (V)

TxOUT -

TxOUT +

Figure 9. Supply Current VS. Supply Voltage for the

SP3243EB

Figure 10. Transmitter Output Voltage VS. Supply

Voltage for the SP3243EB

2.7 3 3.5 4 4.5 5

Supply Voltage (V

)

Supply Current (mA)

1 Transmitter at 250Kbps

2 Transmitters at 15.6Kbps

All drivers loaded with 3K // 1000pF

Table 1. Device Pin Description

PIN NUMBER

SP3243EB

SOIC, SSOP, SP3243EBCR

NAME FUNCTION SP3223EB TSSOP QFN

EN Receiver Enable. Apply logic LOW for normal operation. 1 - -

Apply logic HIGH to disable the receiver outputs (high-Z state).

C1+ Positive terminal of the voltage doubler charge-pump capacitor. 2 28 28

V+ Regulated +5.5V output generated by the charge pump. 3 27 26

C1- Negative terminal of the voltage doubler charge-pump capacitor. 4 24 22

C2+ Positive terminal of the inverting charge-pump capacitor. 5 1 29

C2- Negative terminal of the inverting charge-pump capacitor. 6 2 31

V- Regulated -5.5V output generated by the charge pump. 7 3 32

R1IN RS-232 receiver input. 16 4 2

R2IN RS-232 receiver input. 9 5 3

R3IN RS-232 receiver input. - 6 4

R4IN RS-232 receiver input. - 7 5

R5IN RS-232 receiver input. - 8 6

R1OUT TTL/CMOS receiver output. 15 19 17

R2OUT TTL/CMOS receiver output. 10 18 16

R2OUT Non-inverting receiver-2 output, active in shutdown. - 20 18

R3OUT TTL/CMOS receiver output. - 17 15

R4OUT TTL/CMOS receiver output. - 16 14

R5OUT TTL/CMOS receiver output. - 15 13

STATUS TTL/CMOS Output indicating online and shutdown status. 11 21 19

T1IN TTL/CMOS driver input. 13 14 12

T2IN TTL/CMOS driver input. 12 13 11

T3IN TTL/CMOS driver input. - 12 10

ONLINE Apply logic HIGH to override Auto-Online circuitry keeping 14 23 21

drivers active (SHUTDOWN must also be logic HIGH,

refer to Table 2).

T1OUT RS-232 driver output. 17 9 7

T2OUT RS-232 driver output. 8 10 8

T3OUT RS-232 driver output. - 11 9

GND Ground. 18 25 23

VCC +3.0V to +5.5V supply voltage. 19 26 25

SHUTDOWN Apply logic LOW to shut down drivers and charge pump. 20 22 20

This overrides all AUTO ON-LINE® circuitry and ONLINE

(refer to Table 2).

NC No Connection - - 1,24,27,30

Figure 12. SP3243EB Pinout Configuration

Figure 11. SP3223EB Pinout Configuration

V-

417

SHUTDOWN

C1+

V+

C1-

C2+

C2-

ONLINE

GND

VCC

OUT

STATUS

10 11

OUT

SP3223EB

OUT T

OUT

425

22 SHUTDOWN

C2-

V-

IN ONLINE

C2+

C1-

GND

V+

STATUS

11 18

15 R

OUT

IN R

OUT

SP3243EB

C1+

Figure 13. SP3243EB QFN (QFN) Pinout Configuration

SP3243EB

V-

C2-

C2+

C1+

V+

OUT

GND

C1-

ONLINE

SHUTDOWN

STATUS

OUT

Figure 14. SP3223EB Typical Operating Circuit

SP3223EB

GND

C1+

C1-

C2+

C2-

V+

V-

0.1µF

+C3

0.1µF

RS-232

OUTPUTS

RS-232

INPUTS

TTL/CMOS

INPUTS

+3.3V to +5V

SHUTDOWN

5kΩ

OUT

15 16

5kΩ

OUT

10 9

TTL/CMOS

OUTPUTS

ONLINE

OUT

11 STATUS

To µP Supervisor

Circuit

Figure 15. SP3243EB Typical Operating Circuit

SP3243EB

5kΩ

GND

C1+

C1-

C2+

C2-

V+

V-

0.1µF

+C3

0.1µF

0.1µ

RS-232

OUTPUTS

RS-232

INPUTS

TTL/CMOS

INPUTS

TTL/CMOS

OUTPUTS

To µP Supervisor

Circuit

OUT R

OUT

IN T

OUT

ONLINE

SHUTDOWN

STATUS

DESCRIPTION

The SP3223EB and SP3243EB transceivers meet

the EIA/TIA-232 and ITU-T V.28/V.24 com-

munication protocols and can be implemented

in battery-powered, portable, or hand-held ap-

plications such as notebook or palmtop comput-

ers. The SP3223EB and SP3243EB devices

feature Sipex's proprietary and patented (U.S.--

5,306,954) on-board charge pump circuitry that

generates ±5.5V RS-232 voltage levels from a

single +3.0V to +5.5V power supply. The

SP3223EB and SP3243EB devices can operate

at a data rate of 250kbps fully loaded.

The SP3223EB is a 2-driver/2-receiver device,

and the SP3243EB is a 3-driver/5-receiver de-

vice ideal for portable or hand-held applications.

The SP3243EB includes one complementary

always-active receiver that can monitor an

external device (such as a modem) in shutdown.

This aids in protecting the UART or serial

controller IC by preventing forward biasing

of the protection diodes where VCC may be

disconnected.

The SP3223EB and SP3243EB series is an ideal

choice for power sensitive designs. The

SP3223EB and SP3243EB devices feature

AUTO ON-LINE® circuitry which reduces the

power supply drain to a 1µA supply current. In

many portable or hand-held applications, an RS-

232 cable can be disconnected or a connected

peripheral can be turned off. Under these condi-

tions, the internal charge pump and the drivers

will be shut down. Otherwise, the system auto-

matically comes online. This feature allows de-

sign engineers to address power saving concerns

without major design changes.

THEORY OF OPERATION

The SP3223EB and SP3243EB series is made up

of four basic circuit blocks:

1. Drivers,

2. Receivers,

3. the Sipex proprietary charge pump, and

4. AUTO ON-LINE® circuitry.

Drivers

The drivers are inverting level transmitters that

convert TTL or CMOS logic levels to 5.0V EIA/

TIA-232 levels with an inverted sense relative to

the input logic levels. Typically, the RS-232

output voltage swing is +5.4V with no load and

+5V minimum fully loaded. The driver outputs

are protected against infinite short-circuits to

ground without degradation in reliability. These

drivers comply with the EIA-TIA-232F and all

previous RS-232 versions. Unused driver inputs

should be connected to GND or VCC.

The drivers can guarantee a data rate of 250kbps

fully loaded with 3kΩ in parallel with 1000pF,

ensuring compatibility with PC-to-PC commu-

nication software.

The slew rate of the driver output is internally

limited to a maximum of 30V/µs in order to

meet the EIA standards (EIA RS-232D 2.1.7,

Paragraph 5). The transition of the loaded

output from HIGH to LOW also meets the

monotonicity requirements of the standard.

Figure 16. Interface Circuitry Controlled by Micropro-

cessor Supervisory Circuit

SP3243EB

5KΩ

GND

C1+

C1-

C2+

C2-

V+

V-

VCC

0.1µF

+C3

0.1µF

RS-232

OUTPUTS

RS-232

INPUTS

VCC

OUT R

OUT

IN T

OUT

ONLINE

SHUTDOWN

STATUS

UART

Serial C

Supervisor

TxD

RTS

DTR

RxD

CTS

DSR

DCD

VCC

VIN

RESET

The SP3223EB and SP3243EB drivers can main-

tain high data rates up to 250kbps fully loaded.

Figure 17. shows a loopback test circuit used to

test the SP3243EB RS-232 Drivers. Figure 18

shows the test results of the loopback circuit with

all three drivers active at 120kbps with typical

RS-232 loads in parallel with 1000pF capacitors.

Figure 19 shows the test results where one driver

Table 2. SHUTDOWN and EN Truth Tables

Note: In AUTO ON-LINE® Mode where ONLINE =

GND and SHUTDOWN = VCC, the device will shut down

if there is no activity present at the Receiver inputs.

Figure 17. Loopback Test Circuit for RS-232 Driver

Data Transmission Rates

was active at 250kbps and all three drivers loaded

with an RS-232 receiver in parallel with a 1000pF

capacitor. A solid RS-232 data transmission

rate of 250kbps provides compatibility with many

designs in personal computer peripherals and

LAN applications.

Receivers

The receivers convert ±5.0V EIA/TIA-232

levels to TTL or CMOS logic output levels. All

receivers have an inverting output that can be

disabled by using the EN pin.

Figure 18. Loopback Test Circuit All Drivers at 120kbps Figure 19. Loopback Test Circuit One Driver at 250kbps

SP3223EB

SP3243EB

GND

C1+

C1-

C2+

C2-

V+

V-

0.1µF

+C3

0.1µF

TTL/CMOS

INPUTS

+3V to +5V

SHUTDOWN

5kΩ

OUT

5kΩ

OUT

TTL/CMOS

OUTPUTS

ONLINE

OUT

STATUS

To µP Supervisor

Circuit

1000pF 1000pF

DEVICE: SP3223EB

SHUTDOWN EN TXOUT RXOUT

00High Z Active

01High Z High Z

10Active Active

11Active High Z

DEVICE: SP3243EB

SHUTDOWN TXOUT RXOUT R2OUT

0High Z High Z Active

1Active Active Active

Receivers are active when the AUTO ON-LINE®

circuitry is enabled or when in shutdown.

During the shutdown, the receivers will continue

to be active. If there is no activity present at the

receivers for a period longer than 100µs or when

SHUTDOWN is enabled, the device goes into a

standby mode where the circuit draws 1µA.

Driving EN to a logic HIGH forces the outputs of

the receivers into high-impedance. The truth

table logic of the SP3223EB and SP3243EB driver

and receiver outputs can be found in Table 2.

The SP3243EB includes an additional non-in-

verting receiver with an output R2OUT. R2OUT

is an extra output that remains active and moni-

tors activity while the other receiver outputs are

forced into high impedance. This allows Ring

Indicator (RI) from a peripheral to be monitored

without forward biasing the TTL/CMOS inputs

of the other devices connected to the receiver

outputs.

Since receiver input is usually from a transmis-

sion line where long cable lengths and system

interference can degrade the signal, the inputs

have a typical hysteresis margin of 300mV. This

ensures that the receiver is virtually immune to

noisy transmission lines. Should an input be left

unconnected, an internal 5KΩ pulldown resistor

to ground will commit the output of the receiver

to a HIGH state.

Charge Pump

The charge pump is a Sipex–patented design

(U.S. 5,306,954) and uses a unique approach

compared to older less–efficient designs. The

charge pump still requires four external

capacitors, but uses a four–phase voltage

shifting technique to attain symmetrical 5.5V

power supplies. The internal power supply

consists of a regulated dual charge pump that

provides output voltages 5.5V regardless of the

input voltage (VCC) over the +3.0V to +5.5V

range. This is important to maintain compliant

RS-232 levels regardless of power supply

fluctuations.

The charge pump operates in a discontinuous

mode using an internal oscillator. If the output

voltages are less than a magnitude of 5.5V, the

charge pump is enabled. If the output voltages

exceed a magnitude of 5.5V, the charge pump is

disabled. This oscillator 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 VCC. Cl+ is

then switched to GND and the charge in C1– is

transferred to C2–. Since C2+ is connected to

VCC, the voltage potential across capacitor C2 is

now 2 times VCC.

Phase 2

— VSS transfer — Phase two of the clock

connects the negative terminal of C2 to the VSS

storage capacitor and the positive terminal of C2

to GND. This transfers a negative generated

voltage to C3. This generated voltage is

regulated to a minimum voltage of -5.5V.

Simultaneous with the transfer of the voltage to

C3, the positive side of capacitor C1 is switched

to VCC and the negative side is connected to

GND.

Phase 3

— VDD charge storage — The third phase of the

clock is identical to the first phase — the charge

transferred in C1 produces –VCC in the negative

terminal of C1, which is applied to the negative

side of capacitor C2. Since C2+ is at VCC, the

voltage potential across C2 is 2 times VCC.

Phase 4

— VDD transfer — The fourth phase of the clock

connects the negative terminal of C2 to GND,

and transfers this positive generated voltage

across C2 to C4, the VDD storage capacitor. This

voltage is regulated to +5.5V. At this voltage,

the internal oscillator is disabled. Simultaneous

with the transfer of the voltage to C4, the

positive side of capacitor C1 is switched to VCC

and the negative side is connected to GND,

allowing the charge pump cycle to begin again.

The charge pump cycle will continue as long as

the operational conditions for the internal

oscillator are present.

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.

Figure 20. AUTO ON-LINE® Timing Waveforms

RECEIVER

RS-232 INPUT

VOLTAGES

STATUS

+5V

-5V

tSTSL

tSTSH

tONLINE

VCC

DRIVER

RS-232 OUTPUT

VOLTAGES

+2.7V

-2.7V

The clock rate for the charge pump typically

operates at 250kHz. The external capacitors can

be as low as 0.1µF with a 16V breakdown

voltage rating.

Figure 22. Charge Pump — Phase 2

Figure 23. Charge Pump Waveforms

= +5V

–10V

Storage Capacitor

–

––

Figure 24. Charge Pump — Phase 3

= +5V

–5V

+5V

–5V

Storage Capacitor

–

––

Figure 25. Charge Pump — Phase 4

= +5V

+10V

Storage Capacitor

–

––

VCC = +5V

–5V –5V

+5V

VSS Storage Capacitor

VDD Storage Capacitor

C1C2

–

––

Figure 21. Charge Pump — Phase 1

Ch1 2.00V Ch2 2.00V M 1.00µs Ch1 1.96V

T[]

+6V

a) C2+

b) C2-

-6V

Figure 26. SP3243EB Driver Output Voltages vs. Load

Current per Transmitter

Figure 27. Circuit for the connectivity of the SP3243EB with a DB-9 connector

-2

-4

-6

Transmitter Output Voltage [V]

Load Current Per Transmitter [mA]

Vout+

Vout-

0.62

0.869

0.939

1.02

1.12

1.23

1.38

1.57

1.82

2.67

3.46

4.93

8.6

DB-9

Connector

6. DCE Ready

7. Request to Send

8. Clear to Send

9. Ring Indicator

DB-9 Connector Pins:

1. Received Line Signal Detector

2. Received Data

3. Transmitted Data

4. Data Terminal Ready

5. Signal Ground (Common)

SP3243EB

5kΩ

GND

C1+

C1-

C2+

C2-

V+

V-

0.1µF

+C3

0.1µF

To µP Supervisor

Circuit

OUT R

OUT

IN T

OUT

ONLINE

SHUTDOWN

STATUS

Table 3. AUTO ON-LINE® Logic

Figure 28. Stage I of AUTO ON-LINE® Circuitry

Figure 29. Stage II of AUTO ON-LINE® Circuitry

RS-232

Receiver Block

RXINACT

Inactive Detection Block

RXIN RXOUT

INACT R

INACT

Delay

Stage

Delay

Stage

Delay

Stage

Delay

Stage Delay

Stage

SHUTDOWN

STATUS

RS - 232 SIGNAL SHUTDOWN ONLINE INPUT STATUS OUTPUT TRANCEIVER

AT RECEIVER INPUT STATUS

INPUT

YES HIGH LOW HIGH Normal Operation

(AUTO ON-LINE®)

NO HIGH HIGH LOW Normal Operation

NO HIGH LOW LOW Sutdown

(AUTO ON-LINE® )

YES LOW HIGH/LOW HIGH Shutdown

NO LOW HIGH/LOW LOW Shutdown

AUTO ON-LINE® Circuitry

The SP3223EB and SP3243EB devices have a

patent pending AUTO ON-LINE® circuitry on

board that saves power in applications such as

laptop computers, palmtop (PDA) computers,

and other portable systems.

The SP3223EB and SP3243EB devices incorpo-

rate an AUTO ON-LINE® circuit that automati-

cally enables itself when the external transmit-

ters are enabled and the cable is connected.

Conversely, the AUTO ON-LINE® circuit also

disables most of the internal circuitry when the

device is not being used and goes into a standby

mode where the device typically draws 1µA.

This function can also be externally controlled

by the ONLINE pin. When this pin is tied to a

logic LOW, the AUTO ON-LINE® function is

active. Once active, the device is enabled until

there is no activity on the receiver inputs. The

receiver input typically sees at least ±3V, which

are generated from the transmitters at the other

end of the cable with a ±5V minimum. When the

external transmitters are disabled or the cable is

disconnected, the receiver inputs will be pulled

down by their internal 5kΩ resistors to ground.

When this occurs over a period of time, the

internal transmitters will be disabled and the

device goes into a shutdown or standby mode.

When ONLINE is HIGH, the AUTO ON-LINE®

mode is disabled.

The AUTO ON-LINE® circuit has two stages:

1) Inactive Detection

2) Accumulated Delay

The first stage, shown in Figure 28, detects an

inactive input. A logic HIGH is asserted on

RXINACT if the cable is disconnected or the

external transmitters are disabled. Otherwise,

RXINACT will be at a logic LOW. This circuit is

duplicated for each of the other receivers.

The second stage of the AUTO ON-LINE® cir-

cuitry, shown in Figure 29, processes all the

receiver's RXINACT signals with an accumu-

lated delay that disables the device to a 1µA

supply current.

The STATUS pin goes to a logic LOW when the

cable is disconnected, the external transmitters

are disabled, or the SHUTDOWN pin is

invoked. The typical accumulated delay is

around 20µs.

When the SP3223EB and SP3243EB drivers or

internal charge pump are disabled, the supply

current is reduced to 1µA. This can commonly

occur in hand-held or portable applications where

the RS-232 cable is disconnected or the RS-232

drivers of the connected peripheral are turned off.

The AUTO ON-LINE® mode can be disabled by

the SHUTDOWN pin. If this pin is a logic LOW,

the AUTO ON-LINE® function will not operate

regardless of the logic state of the ONLINE pin.

Table 3 summarizes the logic of the AUTO ON-

LINE® operating modes. The truth table logic of

the SP3223EB and SP3243EB driver and re-

ceiver outputs can be found in Table 2.

The STATUS pin outputs a logic LOW signal

if the device is shutdown. This pin goes to a

logic HIGH when the external transmitters are

enabled and the cable is connected.

When the SP3223EB and SP3243EB devices

are shut down, the charge pumps are turned off.

V+ charge pump output decays to VCC, the

V- output decays to GND. The decay time will

depend on the size of capacitors used for the

charge pump. Once in shutdown, the time

required to exit the shut down state and have

valid V+ and V- levels is typically 200µs.

For easy programming, the STATUS can be

used to indicate DTR or a Ring Indicator signal.

Tying ONLINE and SHUTDOWN together

will bypass the AUTO ON-LINE® circuitry so

this connection acts like a shutdown input pin.

ESD TOLERANCE

The SP3223EB/3243EB series incorporates

ruggedized ESD cells on all driver output and

receiver input pins. The ESD structure is

improved over our previous family for more

rugged applications and environments sensitive

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 electrostatic energy and

discharge it to an integrated circuit. The

simulation is performed by using a test model as

shown in Figure 30. 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

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 31. 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

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.

SW1 SW2

Device

Under

Test

DC Power

Source

SW1 SW2

Figure 30. ESD Test Circuit for Human Body Model

DEVICE PIN HUMAN BODY IEC1000-4-2

TESTED MODEL Air Discharge Direct Contact Level

Driver Outputs ±15kV ±15kV ±8kV 4

Receiver Inputs ±15kV ±15kV ±8kV 4

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

The circuit model in Figures 29 and 30 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.

Figure 32. ESD Test Waveform for IEC1000-4-2

t=0ns t=30ns

15A

30A

t ➙

i ➙

Figure 31. ESD Test Circuit for IEC1000-4-2

Table 4. Transceiver ESD Tolerance Levels

ALTERNATE

END PINS

(BOTH ENDS)

D1 = 0.005" min.

(0.127 min.)

PACKAGE: PLASTIC

DUAL–IN–LINE

(NARROW)

A = 0.210" max.

(5.334 max).

A1 = 0.015" min.

(0.381min.)

e = 0.100 BSC

(2.540 BSC)

= 0.300 BSC

(7.620 BSC)

DIMENSIONS (Inches)

Minimum/Maximum

(mm)

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)

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°)

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°)

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)

1.385/1.454

(35.17/36.90)

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°)

PACKAGE: PLASTIC SHRINK

SMALL OUTLINE

(SSOP)

DIMENSIONS (Inches)

Minimum/Maximum

(mm)

20–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)

0.278/0.289

(7.07/7.33)

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°)

24–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)

0.317/0.328

(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°)

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°)

16–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)

0.239/0.249

(6.07/6.33)

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)

28–PIN

0.090/0.104

(2.29/2.649)

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°)

Gage

Plane

1.0 OIA

0.169 (4.30)

0.177 (4.50)

0.252 BSC (6.4 BSC)

0’-8’ 12’REF

0.039 (1.0)

e/2

0.039 (1.0)

0.126 BSC (3.2 BSC)

0.007 (0.19)

0.012 (0.30)

0.033 (0.85)

0.037 (0.95)

0.002 (0.05)

0.006 (0.15)

0.043 (1.10) Max

(θ3)

1.0 REF

0.020 (0.50)

0.026 (0.75)

(θ1)

0.004 (0.09) Min

0.010 (0.25)

(θ2)

0.008 (0.20)

DIMENSIONS

in inches (mm) Minimum/Maximum

Symbol 20 Lead 28 Lead

D 0.252/0.260 0.378/0.386

(6.40/6.60) (9.60/9.80)

e 0.026 BSC 0.026 BSC

(0.65 BSC) (0.65 BSC)

PACKAGE: PLASTIC THIN

SMALL OUTLINE

(TSSOP)

NX K

NX L

NX K

NX b

0.80 0.90 1.00

0 0.02 0.05

Dimensions in

(mm)

32 PIN QFN

JEDECMO220

(VHHD-4)

0 0.65 1.00

0.20 REF

0.35 0.40 0.45

MIN NOM MAX

3.50 3.65 3.80

E2 3.50 3.65 3.80

5.00 BSC

NE 8

32 PIN QFN

e0.50 BSC

b 0.18 0.25 0.30

0º - 14º

N32

SEATING PLANE

K0.20 - -

PACKAGE: 32 PIN QFN

Part Number Temperature Range Package Types

SP3223EBCP .................................................... 0°C to +70°C -------------------------------------------- 20-pin PDIP

SP3223EBCA .................................................... 0°C to +70°C ------------------------------------------- 20-pin SSOP

SP3223EBCA/TR .............................................. 0°C to +70°C ------------------------------------------- 20-pin SSOP

SP3223EBCY .................................................... 0°C to +70°C ----------------------------------------- 20-pin TSSOP

SP3223EBCY/TR .............................................. 0°C to +70°C ----------------------------------------- 20-pin TSSOP

SP3223EBEP .................................................. -40°C to +85°C ------------------------------------------- 20-pin PDIP

SP3223EBEA .................................................. -40°C to +85°C ------------------------------------------ 20-pin SSOP

SP3223EBEA/TR ............................................ -40°C to +85°C ------------------------------------------ 20-pin SSOP

SP3223EBEY .................................................. -40°C to +85°C ---------------------------------------- 20-pin TSSOP

SP3223EBEY/TR ............................................ -40°C to +85°C ---------------------------------------- 20-pin TSSOP

SP3243EBCT .................................................... 0°C to +70°C ----------------------------------------- 28-pin WSOIC

SP3243EBCT/TR .............................................. 0°C to +70°C ----------------------------------------- 28-pin WSOIC

SP3243EBCA .................................................... 0°C to +70°C ------------------------------------------- 28-pin SSOP

SP3243EBCA/TR .............................................. 0°C to +70°C ------------------------------------------- 28-pin SSOP

SP3243EBCY ................................................... -0°C to +70°C ----------------------------------------- 28-pin TSSOP

SP3243EBCY/TR ............................................. -0°C to +70°C ----------------------------------------- 28-pin TSSOP

SP3243EBCR ................................................... -0°C to +70°C --------------------------------------------- 32-pin QFN

SP3243EBCR/TR ............................................. -0°C to +70°C --------------------------------------------- 32-pin QFN

SP3243EBET .................................................. -40°C to +85°C ---------------------------------------- 28-pin WSOIC

SP3243EBET/TR ............................................ -40°C to +85°C ---------------------------------------- 28-pin WSOIC

SP3243EBEA .................................................. -40°C to +85°C ------------------------------------------ 28-pin SSOP

SP3243EBEA/TR ............................................ -40°C to +85°C ------------------------------------------ 28-pin SSOP

SP3243EBEY .................................................. -40°C to +85°C ---------------------------------------- 28-pin TSSOP

SP3243EBEY/TR ............................................ -40°C to +85°C ---------------------------------------- 28-pin TSSOP

SP3243EBER .................................................. -40°C to +85°C -------------------------------------------- 32-pin QFN

SP3243EBER/TR ............................................ -40°C to +85°C -------------------------------------------- 32-pin QFN

Corporation

ANALOG 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 herein; neither does it convey any license under its patent rights nor the rights of others.

Sipex Corporation

Headquarters and

Sales Office

233 South Hillview Drive

Milpitas, CA 95035

TEL: (408) 934-7500

FAX: (408) 935-7600

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

Example: SP3243EBCY/TR = standard; SP3243EBCY-L/TR = lead free

/TR = Tape and Reel

Pack quantity is 1,500 for SSOP, TSSOP and WSOIC. Pack quantity is 2,500 QFN

ORDERING INFORMATION

DATE REVISION DESCRIPTION

6/2/04 A Added QFN package.

REVISION HISTORY