DRV593_15 Datasheet, PDF(15/27 Page) Texas Instruments – 3−A HIGH−EFFICIENCY PWM POWER DRIVER

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DRV593_15 Datasheet, PDF (15/27 Pages) Texas Instruments – 3−A HIGH−EFFICIENCY PWM POWER DRIVER

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DRV593

DRV594

SLOS401C â OCTOBER 2002 â REVISED JULY 2010

For the DRV593 and DRV594, the differential output switching frequency is typically selected to be 500 kHz. The

resonant frequency for the filter is typically chosen to be at least one order of magnitude lower than the switching

frequency. Equation 5 may then be simplified to give the following magnitude Equation 6. These equations

assume the use of the filter in Figure 22.

Ç Ç Å¤ Å¤ HLP dB + â40 log

Ç¸LC

fs + 500 kHz (DRV593 or DRV594 switching frequency)

(6)

If L=10 mH and C=10 mF, the cutoff frequency is 15.9 kHz, which corresponds to â60 dB of attenuation at the 500

kHz switching frequency. For VDD = 5 V, the amount of ripple voltage at the TEC element is approximately 5

mV.

The average TEC element has a resistance of 1.5 â¦, so the ripple current through the TEC is approximately 3.4

mA. At the 3-A maximum output current of the DRV593 and DRV594, this 5.4 mA corresponds to 0.11% ripple

current, causing less than 0.0001% reduction of the maximum temperature differential of the TEC element (see

Equation 4).

LC FILTER IN THE TIME DOMAIN

The ripple current of an inductor may be calculated using Equation 7:

Ç Ç DIL +

VOâVTEC DTs

D + duty cycle (0.5 worst case)

Ts + 1Åfs + 1Å500 kHz

(7)

For VO = 5 V, VTEC = 2.5 V, and L = 10 mH, the inductor ripple current is 250 mA. To calculate how much of that

ripple current flows through the TEC element, however, the properties of the filter capacitor must be considered.

For relatively small capacitors (less than 22 mF) with very low equivalent series resistance (ESR, less than

10 mâ¦, such as ceramic capacitors, the following Equation 8 may be used to estimate the ripple voltage on the

capacitor due to the change in charge:

Ç Ç DVC

Ç1âDÇ

VTEC

D + duty cycle

fs + 500 kHz

Ç¸LC

(8)

For L = 10 mH and C = 10 mF, the cutoff frequency, fo, is 15.9 kHz. For worst case duty cycle of 0.5 and

VTEC=2.5 V, the ripple voltage on the capacitors is 6.2 mV. The ripple current may be calculated by dividing the

ripple voltage by the TEC resistance of 1.5â¦, resulting in a ripple current through the TEC element of 4.1 mA.

Note that this is similar to the value calculated using the frequency domain approach.

For larger capacitors (greater than 22 mF) with relatively high ESR (greater than 100 mâ¦), such as electrolytic

capacitors, the ESR dominates over the charging/discharging of the capacitor. The following simple Equation 9

may be used to estimate the ripple voltage:

DVC + DIL RESR

DIL + inductor ripple current

RESR + filter capacitor ESR

(9)

Product Folder Link(s): DRV593 DRV594

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