ICL3217EIB Datasheet ICL3207ECAZ-T, ICL3207ECAZ, ICL3207ECBZ | P7-P9

This automatic powerdown feature provides additional

system power savings without changes to the existing

operating system or hardware.

Utilizing power management circuitry, to power down the

rest of the communication circuitry (e.g., the UART) when

the ICL3217E powers down, produces even greater power

savings. Connecting a transition detector to the V- pin (see

Figure 3) is an easy way for the power management logic to

determine when the ICL3217E enters and exits powerdown.

Capacitor Selection

The charge pumps require 0.1F, or greater, capacitors for

3.3V operation. With 0.1F capacitors, five percent tolerance

supplies (e.g., 3.14V minimum) deliver greater than 5V

transmitter swings at full data rate, while ten percent

tolerance supplies (e.g., 2.97V minimum) deliver 4.95V

transmitter swings. If greater than 5V transmitter swings

are required with a 10% tolerance 3.3V supply, 0.22F

capacitors are recommended (see Table 3). Existing 5V

applications typically utilize either 0.1F or 1F capacitors,

and the ICL32X7E works well with either value. New 5V

designs should use 0.22F capacitors for the best results.

For other supply voltages refer to Table 3 for capacitor

values. Do not use values smaller than those listed in

Table 3. Increasing the capacitor values (by a factor of two)

reduces ripple on the transmitter outputs and slightly

reduces power consumption. C

, C

, and C

can be

increased without increasing C

’s value, however, do not

increase C

without also increasing C

, C

, and C

maintain the proper ratios (C

to the other capacitors).

When using minimum required capacitor values, make sure

that capacitor values do not degrade excessively with

temperature. If in doubt, use capacitors with a larger nominal

value. The capacitor’s equivalent series resistance (ESR)

usually rises at low temperatures and it influences the

amount of ripple on V+ and V-

Power Supply Decoupling

In most circumstances a 0.1F bypass capacitor is

adequate. In applications that are particularly sensitive to

power supply noise, decouple V

to ground with a

capacitor of the same value as the charge-pump capacitor C

Connect the bypass capacitor as close as possible to the IC.

Transmitter Outputs when Exiting

Powerdown

Figure 6 shows the response of two ICL3217E transmitter

outputs when exiting powerdown mode. As they activate, the

two transmitter outputs properly go to opposite RS-232

levels, with no glitching, ringing, nor undesirable transients.

Each transmitter is loaded with 3kin parallel with 2500pF.

Note that the transmitters enable only when the magnitude

of the supplies exceed approximately 3V.

FIGURE 4. DEFINITION OF VALID RS-232 RECEIVER

LEVELS

0.3V

-0.3V

-2.7V

2.7V

INVALID LEVEL - POWERDOWN OCCURS AFTER 30s

VALID RS-232 LEVEL - ICL3217E IS ACTIVE

INDETERMINATE - POWERDOWN MAY OR

MAY NOT OCCUR

INDETERMINATE - POWERDOWN MAY OR

MAY NOT OCCUR

RECEIVER

INPUTS

TRANSMITTER

OUTPUTS

V+

V-

INVALID

REGION

}

FIGURE 5. AUTOMATIC POWERDOWN TIMING DIAGRAM

AUTOPWDN

PWR UP (t

)

TABLE 3. REQUIRED CAPACITOR VALUES

(V) C

(F) C

, C

(F)

3.15 to 3.6 0.1 0.1

3.0 to 3.6 0.22 0.22

4.5 to 5.5 0.1 to 1.0 0.1 to 1.0

3.0 to 5.5 0.22 0.22

TIME (20s/DIV.)

2V/DIV

5V/DIV

= +3.3V

C1 - C4 = 0.1F

FIGURE 6. TRANSMITTER OUTPUTS WHEN EXITING

POWERDOWN (ICL3217E ONLY)

ICL3207E, ICL3217E

Operation down to 2.7V

ICL32X7E transmitter outputs meet RS-562 levels (3.7V)

with V

as low as 2.7V. RS-562 levels typically ensure inter

operability with RS-232 devices.

High Data Rates

The ICL32XX maintain the RS-232 5V minimum transmitter

output voltages even at high data rates. Figure 7 details a

transmitter loopback test circuit, and Figure 8 illustrates the

loopback test result at 120kbps. For this test, all transmitters

were simultaneously driving RS-232 loads in parallel with

1000pF, at 120kbps. Figure 9 shows the loopback results for

a single transmitter driving 1000pF and an RS-232 load at

250kbps. The static transmitters were also loaded with an

RS-232 receiver.

Interconnection with 3V and 5V Logic

The ICL32X7E directly interface with 5V CMOS and TTL

logic families. Nevertheless, with the ICL32X7E at 3.3V, and

the logic supply at 5V, AC, HC, and CD4000 outputs can

drive ICL32X7E inputs, but ICL32X7E outputs do not reach

the minimum V

for these logic families. See Table 4 for

more information.

15kV ESD Protection

All pins on ICL32XX devices include ESD protection

structures, but the ICL32X7E incorporate advanced

structures which allow the RS-232 pins (transmitter outputs

and receiver inputs) to survive ESD events up to 15kV. The

RS-232 pins are particularly vulnerable to ESD damage

because they typically connect to an exposed port on the

exterior of the finished product. Simply touching the port

pins, or connecting a cable, can cause an ESD event that

might destroy unprotected ICs. These new ESD structures

protect the device whether or not it is powered up, protect

without allowing any latchup mechanism to activate, and

don’t interfere with RS-232 signals as large as 25V.

FIGURE 7. TRANSMITTER LOOPBACK TEST CIRCUIT

FIGURE 8. LOOPBACK TEST AT 120kbps

ICL32X7E

1000pF

V+

V-

OUT

C1+

C1-

C2+

C2-

OUT

0.1F

OUT

5s/DIV.

= +3.3V

5V/DIV.

C1 - C4 = 0.1F

FIGURE 9. LOOPBACK TEST AT 250kbps

TABLE 4. LOGIC FAMILY COMPATIBILITY WITH VARIOUS

SUPPLY VOLTAGES

SYSTEM

POWER-SUPPLY

VOLTAGE

(V)

SUPPLY

VOLTAGE

(V) COMPATIBILITY

3.3 3.3 Compatible with all CMOS

families.

5 5 Compatible with all TTL and

CMOS logic families.

5 3.3 Compatible with ACT and HCT

CMOS, and with TTL. ICL32X7

outputs are incompatible with AC,

HC, and CD4000 CMOS inputs.

OUT

2s/DIV.

5V/DIV.

= +3.3V

C1 - C4 = 0.1mF

ICL3207E, ICL3217E

Human Body Model (HBM) Testing

As the name implies, this test method emulates the ESD

event delivered to an IC during human handling. The tester

delivers the charge through a 1.5k current limiting resistor,

making the test less severe than the IEC61000 test which

utilizes a 330 limiting resistor. The HBM method

determines an ICs ability to withstand the ESD transients

typically present during handling and manufacturing. Due to

the random nature of these events, each pin is tested with

respect to all other pins. The RS-232 pins on “E” family

devices can withstand HBM ESD events to 15kV.

IEC61000-4-2 Testing

The IEC61000 test method applies to finished equipment,

rather than to an individual IC. Therefore, the pins most likely

to suffer an ESD event are those that are exposed to the

outside world (the RS-232 pins in this case), and the IC is

tested in its typical application configuration (power applied)

rather than testing each pin-to-pin combination. The lower

current limiting resistor coupled with the larger charge

storage capacitor yields a test that is much more severe than

the HBM test. The extra ESD protection built into this

device’s RS-232 pins allows the design of equipment

meeting level 4 criteria without the need for additional board

level protection on the RS-232 port.

AIR-GAP DISCHARGE TEST METHOD

For this test method, a charged probe tip moves toward the

IC pin until the voltage arcs to it. The current waveform

delivered to the IC pin depends on approach speed,

humidity, temperature, etc., so it is difficult to obtain

repeatable results. The “E” device RS-232 pins withstand

15kV air-gap discharges.

CONTACT DISCHARGE TEST METHOD

During the contact discharge test, the probe contacts the

tested pin before the probe tip is energized, thereby

eliminating the variables associated with the air-gap

discharge. The result is a more repeatable and predictable

test, but equipment limits prevent testing devices at voltages

higher than 8kV. All “E” family devices survive 8kV contact

discharges on the RS-232 pins.

Typical Performance Curves V

= 3.3V, T

= 25°C

FIGURE 10. TRANSMITTER OUTPUT VOLTAGE vs LOAD

CAPACITANCE

FIGURE 11. SLEW RATE vs LOAD CAPACITANCE

-6.0

-4.0

-2.0

2.0

4.0

6.0

1000 2000 3000 4000 50000

LOAD CAPACITANCE (pF)

TRANSMITTER OUTPUT VOLTAGE (V)

1 TRANSMITTER AT 250kbps

OUT

OTHER TRANSMITTERS AT 30kbps

LOAD CAPACITANCE (pF)

SLEW RATE (V/s)

0 1000 2000 3000 4000 5000

+SLEW

-SLEW

ICL3207E, ICL3217E

P1-P3 P4-P6 P7-P9 P10-P12 P13-P13

ICL3217EIB

Mfr. #:

Buy ICL3217EIB

Manufacturer:

Renesas / Intersil

Description:

IC TXRX RS-232 3-5.5V ESD 24SOIC

Lifecycle:

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ICL3217EIB

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