SN75HVD08_07 Datasheet, PDF(11/19 Page) Texas Instruments – WIDE SUPPLY RANGE RS-485 TRANSCEIVER

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SN75HVD08_07 Datasheet, PDF (11/19 Pages) Texas Instruments – WIDE SUPPLY RANGE RS-485 TRANSCEIVER

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SN75HVD08, SN65HVD08

www.ti.com

SLLS550C â NOVEMBER 2002 â REVISED JULY 2006

APPLICATION INFORMATION

As electrical loads are physically distanced from their

power source, the effects of supply and return line

impedance and the resultant voltage drop must be

accounted. If the supply regulation at the load cannot

be maintained to the circuit requirements, it forces

the use of remote sensing, additional regulation at

the load, bigger or shorter cables, or a combination

of these. The SN65HVD08 eases this problem by

relaxing the supply requirements to allow for more

variation in the supply voltage over typical RS-485

transceivers.

SUPPLY SOURCE IMPEDANCE

In the steady state, the voltage drop from the source

to the load is simply the wire resistance times the

load current as modeled in Figure 15.

VL = VS â 2RSIL

Figure 15. Steady-State Circuit Model

For example, if you were to provide 5-V Â±5% supply

power to a remote circuit with a maximum load

requirement of 0.1 A (one SN65HVD08), the voltage

at the load would fall below the 4.5-V minimum of

most 5-V circuits with as little as 5.8 m of 28-GA

conductors. Table 1 summarizes wire resistance and

the length for 4.5 V and 3 V at the load with 0.1 A of

load current. The maximum lengths would scale

linearly for higher or lower load currents.

not be ignored and decoupling capacitance at the

load is required. The amount depends upon the

magnitude and frequency of the load current change

but, if only powering the SN65HVD08, a 0.1 ÂµF

ceramic capacitor is usually sufficient.

OPTO-ISOLATED DATA BUSES

Long RS-485 circuits can create large ground loops

and pick up common-mode noise voltages in excess

of the range tolerated by standard RS-485 circuits. A

common remedy is to provide galvanic isolation of

the data circuit from earth or local grounds.

Transformers, capacitors, or phototransistors most

often provide isolation of the bus and the local node.

Transformers and capacitors require changing

signals to transfer the information over the isolation

barrier and phototransistors (opto-isolators) can pass

steady-state signals. Each of these methods incurs

additional costs and complexity, the former in clock

encoding and decoding of the data stream and the

latter in requiring an isolated power supply.

Quite often, the cost of isolated power is repeated at

each node connected to the bus as shown in

Figure 16. The possibly lower-cost solution is to

generate this supply once within the system and then

distribute it along with the data line(s) as shown in

Figure 17.

DC-to-DC

Converter

Opto

Isolators

Local Power

Source

Rest of

Board

Table 1. Maximum Cable Lengths for Minimum

Load Voltages at 0.1 A Load

WIRE

SIZE

28 Gage

24 Gage

22 Gage

20 Gage

18 Gage

RESISTANCE

0.213 â¦/m

0.079 â¦/m

0.054 â¦/m

0.034 â¦/m

0.021 â¦/m

4.5 V LENGTH

AT 0.1 A

5.8 m

15.8 m

23.1 m

36.8 m

59.5 m

3-v LENGTH

AT 0.1 A

41.1 m

110.7 m

162.0 m

257.3 m

416.7 m

Under dynamic load requirements, the distributed

inductance and capacitance of the power lines may