HCPL-7510 Datasheet, PDF(15/16 Page) Agilent(Hewlett-Packard)

English

English German Russian Spanish Italian Polish Chinese Japanese Korean French Portuguese	Language :

HCPL-7510 Datasheet, PDF (15/16 Pages) Agilent(Hewlett-Packard) – Isolated Linear Sensing IC

◁

FREQUENTLY ASKED QUESTIONS ABOUT THE HCPL-7510

1. THE BASICS

1.1: Why should I use the HCPL-7510 for sensing current when Hall-effect sensors are available which donât need an

isolated supply voltage?

Available in an auto-insertable, 8-pin DIP package, the HCPL-7510 is smaller than and has better

linearity, offset vs. temperature and Common Mode Rejection (CMR) performance than most Hall-

effect sensors. Additionally, often the required input-side power supply can be derived from the

same supply that powers the gate-drive optocoupler.

2. SENSE RESISTOR AND INPUT FILTER

2.1: Where do I get 10 mâ¦ resistors? I have never seen one that low.

Although less common than values above 10 â¦, there are quite a few manufacturers of resistors

suitable for measuring currents up to 50 A when combined with the HCPL-7510. Example product

information may be found at Daleâs web site (http://www.vishay.com/vishay/dale) and Isotekâs web

site (http://www.isotekcorp.com) and Iwaki Musen Kenkyushoâs website (http://

www.iwakimusen.co.jp) and Micron Electricâs website (http://www.micron-e.co.jp).

2.2: Should I connect both inputs across the sense resistor instead of grounding VIN- directly to pin 4?

This is not necessary, but it will work. If you do, be sure to use an RC filter on both pin 2 (VIN+)

and pin 3 (VIN-) to limit the input voltage at both pads.

2.3: Do I really need an RC filter on the input? What is it for? Are other values of R and C okay?

The input anti-aliasing filter (R=39 â¦, C=0.01 ÂµF) shown in the typical application circuit is

recommended for filtering fast switching voltage transients from the input signal.

(This helps to attenuate higher signal frequencies which could otherwise alias with the input

sampling rate and cause higher input offset voltage.)

Some issues to keep in mind using different filter resistors or capacitors are:

1. (Filter resistor:) The equivalent input resistance for HCPL-7510 is around 700 kâ¦. It is

therefore best to ensure that the filter resistance is not a significant percentage of this value;

otherwise the offset voltage will be increased through the resistor divider effect. [As an

example, if Rfilt = 5.5 kâ¦, then VOS = (Vin * 1%) = 2 mV for a maximum 200 mV input and

VOS will vary with respect to Vin.]

2. The input bandwidth is changed as a result of this different R-C filter configuration. In fact this

is one of the main reasons for changing the input-filter R-C time constant.

3. (Filter capacitance:) The input capacitance of the HCPL-7510 is approximately 1.5 pF. For

proper

operation the switching input-side sampling capacitors must be charged from a

relatively fixed (low impedance) voltage source. Therefore, if a filter capacitor is used it is best

for this capacitor to be a few orders of magnitude greater than the CINPUT (A value of at least

100 pF works well.)

2.4: How do I ensure that the HCPL-7510 is not destroyed as a result of short circuit conditions which

voltage drops across the sense resistor that exceed the ratings of the HCPL-7510âs inputs?

cause

Select the sense resistor so that it will have less than 5 V drop when short circuits occur. The

only other requirement is to shut down the drive before the sense resistor is damaged or its

solder joints melt. This ensures that the input of the HCPL-7510 can not be damaged by sense

resistors going open-circuit.

3. ISOLATION AND INSULATION

3.1: How many volts will the HCPL-7510 withstand?

The momentary (1 minute) withstand voltage is 3750 V rms per UL 1577 and CSA Component

Acceptance Notice #5.

▷