isl3330 Intersil Corporation, isl3330 Datasheet - Page 16

isl3330

Manufacturer Part Number

isl3330

Description

3.3v, ?15kv Esd Protected, Dual Protocol Rs-232/rs-485 Transceivers

Manufacturer

Intersil Corporation

Datasheet

1.ISL3330.pdf (25 pages)

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Proper termination is imperative to minimize reflections

when using the 20Mbps speed option. Short networks using

the medium and slow speed options need not be terminated,

but terminations are recommended unless power dissipation

is an overriding concern. Note that the RS-485 specification

allows a maximum of two terminations on a network,

otherwise the Tx output voltage may not meet the required

In point-to-point, or point-to-multipoint (RS-422) networks,

the main cable should be terminated in its characteristic

impedance (typically 120Ω) at the end farthest from the

driver. In multi-receiver applications, stubs connecting

receivers to the main cable should be kept as short as

possible, but definitely shorter than the limits shown in

Table 4. Multipoint (RS-485) systems require that the main

cable be terminated in its characteristic impedance at both

ends. Again, keep stubs connecting a transceiver to the

main cable as short as possible (refer to Table 4). Avoid

“star”, and other configurations, where there are many

“ends” which would require more than the two allowed

terminations to prevent reflections.

High ESD

All pins on the ISL333x include ESD protection structures

rated at ±2.5kV (HBM), which is good enough to survive

ESD events commonly seen during manufacturing. But the

bus pins (Tx outputs and Rx inputs) are particularly

vulnerable to ESD events because they connect to an

exposed port on the exterior of the finished product. Simply

touching the port pins, or connecting a cable, can destroy an

unprotected port. ISL333x bus pins are fitted with advanced

structures that deliver ESD protection in excess of ±15kV

(HBM), without interfering with any signal in the RS-485 or

the RS-232 range. This high level of protection may

eliminate the need for board level protection, or at the very

least will increase the robustness of any board level scheme.

Small Packages

Competing 3.3V dual protocol ICs are available only in a

20 Ld or 24 Ld SSOP. The ISL3331’s tiny 6mmx6mm QFN

footprint is 36% to 44% smaller than the competing SSOPs.

Flow-Through Pinouts

Even the ISL333x pinouts are features, in that the

“flow-through” design simplifies board layout. Having the bus

pins all on one side of the package for easy routing to a

cable connector, and the Rx outputs and Tx inputs on the

other side for easy connection to a UART, avoids costly and

problematic crossovers. Figure 10 illustrates the

flow-through nature of the pinout.

Low Power Shutdown (SHDN) Mode

The ISL333x enter the SHDN mode when ON = 0, and the

Tx and Rx are disabled (DEN = 0, RXEN = 0, and

RXEN = 1) and the already low supply current drops to as

low as 10µA. SHDN disables the Tx and Rx outputs, and

ISL3330, ISL3331

disables the charge pumps if the port is in RS-232 mode, so

V+ collapses to V

All but 10µA of SHDN I

(SPB, SLEW) pull-up resistors (~10µA/resistor), so SHDN

specification tables indicate the worst case values, but

careful selection of the configuration yields lower currents.

For example, in RS-232 mode the SPB pin isn’t used, so

floating it or tying it high minimizes SHDN I

When enabling from SHDN in RS-232 mode, allow at least

25µs for the charge pumps to stabilize before transmitting

data. If fast enables are required, and I

concern, disable the drivers with the DEN pin to keep the

charge pumps active. The charge pumps aren’t used in

RS-485 mode, thus the transceiver is ready to send or

receive data in less than 2µs, which is much faster than

competing devices that require the charge pump for all

modes of operation.

Internal Loopback Mode

Setting ON = 0, DEN = 1, and RXEN = 1 or RXEN = 0 (QFN

only), places the port in the loopback mode, a mode that

facilitates implementing board level self test functions. In

loopback, internal switches disconnect the Rx inputs from

the Rx outputs, and feed back the Tx outputs to the

appropriate Rx output. This way the data driven at the Tx

input appears at the corresponding Rx output (refer to

“Typical Operating Circuits” on page 6). The Tx outputs

remain connected to their terminals, so the external loads

are reflected in the loopback performance. This allows the

loopback function to potentially detect some common bus

faults such as one or both driver outputs shorted to GND, or

outputs shorted together.

Note that the loopback mode uses an additional set of

receivers, as shown in the “Typical Operating Circuits” on

page 6. These loopback receivers are not standards

compliant, so the loopback mode can’t be used to implement

a half-duplex RS-485 transceiver. See Application Note

AN1401 for specific details on implementing a 3-pin, half

duplex, dual protocol port.

FIGURE 10. ILLUSTRATION OF FLOW-THROUGH PINOUT

varies depending on the ISL333x configuration. The

, and V- collapses to GND.

ISL3330

current is due to control input

µCONTROLLER

isn’t the greatest

UART

ASIC

May 20, 2008

FN6361.0

isl3330 Intersil Corporation, isl3330 Datasheet - Page 16

isl3330

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