LTC1923 LINER [Linear Technology], LTC1923 Datasheet - Page 22

LTC1923

Manufacturer Part Number

LTC1923

Description

High Efficiency Thermoelectric Cooler Controller

Manufacturer

LINER [Linear Technology]

Datasheet

1.LTC1923.pdf (28 pages)

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Current page: 22 of 28
Download datasheet (445Kb)

APPLICATIO S I FOR ATIO

LTC1923

Noise and Slew Rate Control

One disadvantage of switching regulators is that the

switching creates wideband harmonic energy. The high

frequency content can pose problems to associated cir-

cuitry. To combat this issue, the LTC1923 offers a pin

called R

waveforms. Slowing down the transition interval reduces

the harmonic frequency content by spreading out the

energy over a longer time period. The additional transition

time causes some efficiency loss (on the order of 2% to

3%) but significantly improves the high frequency noise

reflected onto the input supply.

Slew rate control is engaged by placing a resistor from

pin should be tied to V

transition at their fastest rate. The resistor value should be

set between 10k (fastest transition) and 300k (slowest tran-

sition). This provides about a 10:1 slew rate range to op-

timize noise performance. The “break-before-make” time

may need to be increased if slew control is implemented,

especially for slower transition rates. Adjustment can be

done by increasing the value of R

maintain the same frequency of operation), to ensure that

the bridge MOSFETs receive nonoverlapping drive.

Power MOSFET Selection

Four external MOSFETs must be selected for use with the

LTC1923; a pair of N-channel MOSFETs for the bottom of

the bridge and a pair of P-channel MOSFETs for the top

diagonals of the bridge. The MOSFETs should be selected

for their R

ratings. A maximum V

sufficient for 5V and 12V bridge applications, but as

mentioned in the High Voltage Application section, a 12V

maximum V

MOSFETs must be selected. There is a trade-off between

tion losses (I

dominant contributor to switching losses. A higher R

MOSFET typically has a smaller gate capacitance and thus

requires less current to charge the gate for the same

complimentary N- and P-channel MOSFETs provide a

SLEW

DS(ON)

DSS

. For 1A TEC applications, the Si9801DY or Si9928DY

to AGND. If slew rate control is not desired, the R

SLEW

and gate charge. The R

DS(ON)

that controls the slew rate of the output drive

TEC

rating is insufficient and higher voltage

, gate charge and maximum V

• R

DS(ON)

allowing the output drivers to

rating of 20V is more than

), while gate charge is a

DS(ON)

affects the conduc-

can be reduced to

DS,

DS(ON)

SLEW

good trade-off between switching and conduction losses.

Above this TEC current level the MOSFETs selected should

have lower R

Efficiency Considerations

Unlike typical voltage regulators, where the output voltage

is fixed, independent of load current, the output voltage of

this regulator changes with load current. This is because

the TEC appears resistive and the current through the TEC

sets the voltage. The output power of the regulator is

defined as:

The efficiency of a switching regulator is equal to the

output power divided by the input power times 100%.

Often it is useful to analyze individual losses to determine

what is limiting the efficiency and which change would

produce the most significant improvement. Efficiency can

be expressed as:

where L1, L2, etc. are the individual losses as a percentage

of input power.

For this application, the main efficiency concern is typi-

cally at the high end of output power. A higher power loss

translates into a greater system temperature rise, result-

ing in the need for heat sinking, increasing both the system

size and cost.

There are three main sources which usually account for

most of the losses in the application shown on the front

page of the data sheet: Input supply current, MOSFET

switching losses and I

1) The input supply current is comprised of the quiescent

current draw from the LTC1658, LTC2053, LTC1923 and

any additional circuitry added. The total maximum supply

current for these devices is on the order of 5mA, which

gives a total power dissipation of 25mW. This power loss

is independent of TEC current.

2) The MOSFET driver current results from switching the

gate capacitance of the power MOSFETs. Each time a gate

is switched from low to high to low again, a packet of

charge dQ moves from V

current, I

Efficiency = 100% – (L1 + L2 + L3 + …)

OUT

= I

GATECHG

TEC

DS(ON)

• R

= 2 • f • (Q

TEC

to maintain the high end efficiency.

R losses.

to ground. The gate charging

+ Q

), where Q

and Q

1923f

are

LTC1923 LINER [Linear Technology], LTC1923 Datasheet - Page 22

LTC1923

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