DC491A datasheet, PDF - EEWORLD Datasheet

DC491A: Descriptionboard demo for ltc1923euh; CategoryDevelopment board/suite/development tools; File Size15KB，1 Pages; ManufacturerLinear ( ADI ); Websitehttp://www.analog.com/cn/index.html; Environmental Compliance

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board demo for ltc1923euh

DESCRIPTION

Demonstration circuit DC388 utilizes the LTC1923 thermoelectric cooler (TEC)

controller. It provides a complete temperature control solution for TEC based

temperature control of fiber-optic lasers. Laser temperature may be controlled at

temperatures above or below ambient with set point stability typically well within .05º C

over widely varying ambient temperature. Temperature set point is established with a

screwdriver driven potentiometer or a 14-bit on-board DAC. Considerably more detail

relating to TEC temperature control issues is available in LTC Application Note AN-89,

“ A Thermoelectric Cooler Temperature Controller for Fiber Optic Lasers.” This

publication should be reviewed before demo board results are evaluated.

QUICK START GUIDE

The Demonstration Board is easy to use if the following procedure is followed:

1. Connect a turned-off power supply (2.7-6V) to the “VDD” and “GND” terminals.

2. Connect a thermistor to the “NTC+” and “NTC – “ terminals. Although the

thermistor is not a polarized device, one of its leads may be committed to the lasers

case ground. If this is so, this lead should be connected to ”NTC -.” Shielded cable

should be used for the thermistor leads, with the shield connected to ground.

3. Temperature set point is determined by the potentiometer or the on-board serial-

addressed DAC. Set JPI jumper connections to the desired temperature set point

source.

4. Connect the TEC leads from the laser to the boards ”TEC+” and “ TEC – “terminals.

Observe polarity.

5. Turn on the power supply. The board will typically pull hundreds of milliamperes

for several seconds. When the temperature set point is reached current will drop and

settle to some sustaining value.

6. Performance optimization for any particular laser is achievable by following the

procedures and guidelines given in LTC Application Note AN-89.

	DC491A	106RN152P-4F1-18.0	LTC1923EGN#TR	DC388B	DC388C	152-17.734475M-18-NR-TR	LTC1923EGN#TRPBF	P-1010K2701JGT1	P0603C4422WBTE	LT1923EGN#pbf
Description	board demo for ltc1923euh	D Type Connector, 152 Contact(s), Male, Crimp Terminal, Plug	IC controller tec HI eff 28ssop	board demo for ltc1923egn	eval board tec ltc1923	Parallel - Fundamental Quartz Crystal, 17.734475MHz Nom, HC-25US, 2 PIN	IC CONTROLLER TEC HI EFF 28SSOP	RESISTOR, THIN FILM, 0.5 W, 5 %, 100 ppm, 2700 ohm, SURFACE MOUNT, 1010, CHIP, ROHS COMPLIANT	Fixed Resistor, Thin Film, 0.125W, 44200ohm, 75V, 0.05% +/-Tol, 5ppm/Cel, Surface Mount, 0603, CHIP	High Efficiency Thermoelectric Cooler Controller
Reach Compliance Code	-	unknown	not_compliant	-	-	compliant	compliant	unknown	unknown	-

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