ISL84762IUZ-T Datasheet ISL84762IRZ-T, ISL84762IRZ, ISL84762IR | P7-P9

FN6105.1

September 15, 2008

Supply Sequencing and Overvoltage Protection

With any CMOS device, proper power supply sequencing is

required to protect the device from excessive input currents

which might permanently damage the IC. All I/O pins contain

ESD protection diodes from the pin to V+ and to GND (see

Figure 9). To prevent forward biasing these diodes, V+ must

be applied before any input signals, and the input signal

voltages must remain between V+ and GND.

If these conditions cannot be guaranteed, then precautions

must be implemented to prohibit the current and voltage at

the logic pin and signal pins from exceeding the maximum

ratings of the switch. The following two methods can be used

to provided additional protection to limit the current in the

event that the voltage at a signal pin or logic pin goes below

ground or above the V+ rail.

Logic inputs can be protected by adding a 1k resistor in

series with the logic input (see Figure 9). The resistor limits

the input current below the threshold that produces

permanent damage, and the sub-microamp input current

produces an insignificant voltage drop during normal

operation.

This method is not acceptable for the signal path inputs.

Adding a series resistor to the switch input defeats the

purpose of using a low r

switch. Connecting Schottky

diodes to the signal pins as shown in Figure 9 will shunt the

fault current to the supply or to ground thereby protecting the

switch. These Schottky diodes must be sized to handle the

expected fault current.

Power-Supply Considerations

The ISL84762 construction is typical of most single supply

CMOS analog switches, in that they have two supply pins:

V+ and GND. V+ and GND drive the internal CMOS

switches and set their analog voltage limits. Unlike switches

with a 4V maximum supply voltage, the ISL84762 4.8V

maximum supply voltage provides plenty of room for the

10% tolerance of 3.6V supplies, as well as room for

overshoot and noise spikes.

The minimum recommended supply voltage is 1.65V but the

part will operate with a supply below 1.5V. It is important to

note that the input signal range, switching times, and

ON-resistance degrade at lower supply voltages. Refer to

the “Electrical Specifications” tables beginning on page 3

and “Typical Performance Curves” beginning on page 8 for

details.

V+ and GND also power the internal logic and level shiftiers.

The level shiftiers convert the input logic levels to switched

V+ and GND signals to drive the analog switch gate

terminals.

This family of switches cannot be operated with bipolar

supplies, because the input switching point becomes

negative in this configuration.

FIGURE 8. V+ SERIES RESISTOR FOR ENHANCED ESD AND

LATCH-UP IMMUNITY

COM

100

V+

GND

OPTIONAL

PROTECTION

RESISTOR

FIGURE 9. OVERVOLTAGE PROTECTION

GND

COM

V+

OPTIONAL

PROTECTION

RESISTOR

OPTIONAL

SCHOTTKY

DIODE

OPTIONAL

SCHOTTKY

DIODE

ISL84762

FN6105.1

September 15, 2008

Logic-Level Thresholds

This switch family is 1.8V CMOS compatible (0.5V and 1.4V)

over a supply range of 2.0V to 3.6V (see Figure 16). At 3.6V

the V

level is about 1.27V. This is still below the 1.8V

CMOS guaranteed high output minimum level of 1.4V, but

noise margin is reduced.

The digital input stages draw supply current whenever the

digital input voltage is not at one of the supply rails. Driving

the digital input signals from GND to V+ with a fast transition

time minimizes power dissipation.

High-Frequency Performance

In 50 systems, the signal response is reasonably flat even

past 30MHz with a -3dB bandwidth of 120MHz (see

Figure 17). The frequency response is very consistent over a

wide V+ range, and for varying analog signal levels.

An OFF switch acts like a capacitor and passes higher

frequencies with less attenuation, resulting in signal

feedthrough from a switch’s input to its output. Off-Isolation

is the resistance to this feedthrough, while crosstalk

indicates the amount of feedthrough from one switch to

another. Figure 18 details the high off-Isolation and crosstalk

rejection provided by this part. At 100kHz, off-Isolation is

about 68dB in 50 systems, decreasing approximately 20dB

per decade as frequency increases. Higher load

impedances decrease off-Isolation and crosstalk rejection

due to the voltage divider action of the switch OFF

impedance and the load impedance.

Leakage Considerations

Reverse ESD protection diodes are internally connected

between each analog-signal pin and both V+ and GND. One of

these diodes conducts if any analog signal exceeds V+ or

GND.

Virtually all the analog leakage current comes from the ESD

diodes to V+ or GND. Although the ESD diodes on a given

signal pin are identical and therefore fairly well balanced,

they are reverse biased differently. Each is biased by either

V+ or GND and the analog signal. This means their leakages

will vary as the signal varies. The difference in the two diode

leakages to the V+ and GND pins constitutes the analog-

signal-path leakage current. All analog leakage current flows

between each pin and one of the supply terminals, not to the

other switch terminal. This is why both sides of a given

switch can show leakage currents of the same or opposite

polarity. There is no connection between the analog signal

Typical Performance Curves T

= +25°C, Unless Otherwise Specified.

FIGURE 10. ON-RESISTANCE vs SUPPLY VOLTAGE vs

SWITCH VOLTAGE

FIGURE 11. ON-RESISTANCE vs SWITCH VOLTAGE

()

COM

(V)

01234

COM

= 100mA

0.1

0.2

0.3

0.4

0.5

0.6

0.7

V+ = 2.7V

V+ = 1.8V

V+ = 3.6V

V+ = 3V

()

COM

(V)

0 0.5 1.0 1.5 2.0 2.5 3.0

0.30

0.32

0.34

0.36

0.38

0.40

0.42

0.44

+25°C

+85°C

-40°C

V+ = 2.7V

COM

= 100mA

ISL84762

FN6105.1

September 15, 2008

FIGURE 12. ON-RESISTANCE vs SWITCH VOLTAGE

FIGURE 13. CHARGE INJECTION vs SWITCH VOLTAGE

FIGURE 14. TURN-ON TIME vs SUPPLY VOLTAGE FIGURE 15. TURN-OFF TIME vs SUPPLY VOLTAGE

FIGURE 16. DIGITAL SWITCHING POINT vs SUPPLY VOLTAGE FIGURE 17. FREQUENCY RESPONSE

Typical Performance Curves T

= +25°C, Unless Otherwise Specified. (Continued)

00.51.01.52.0

()

COM

(V)

+85°C

-40°C

V+ = 1.8V

COM

= 100mA

0.35

0.40

0.45

0.50

0.55

0.60

0.65

+25°C

0 0.5 1.0 1.5 2.0 2.5 3.0

Q (pC)

COM

(V)

V+ = 1.8V

V+ = 3V

100

-50

-25

(ns)

V+ (V)

1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5

+25°C

+85°C

-40°C

OFF

(ns)

V+ (V)

1.0

1.5 2.0 2.5 3.0 3.5 4.0 4.5

+85°C

-40°C

+25°C

V+ (V)

INH

AND V

INL

(V)

1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5

0.3

0.4

0.5

0.6

0.7

0.8

0.9

1.0

1.1

1.2

1.3

1.4

1.5

INH

INL

FREQUENCY (Hz)

-20

NORMALIZED GAIN (dB)

GAIN

PHASE

V+ = 3V

100

PHASE (°)

1M 10M 100M 600M

= 0.2V

P-P

TO 2V

P-P

= 50

ISL84762

P1-P3 P4-P6 P7-P9 P10-P12

ISL84762IUZ-T

Mfr. #:

Buy ISL84762IUZ-T

Manufacturer:

Renesas / Intersil

Description:

Analog Switch ICs ANALO SWITCH DL SPDT 0 4OHM S 1 65V 3 6V

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