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参数资料
| 型号: | ADN8830ACPZ-REEL |
| 厂商: | Analog Devices Inc |
| 文件页数: | 8/22页 |
| 文件大小: | 0K |
| 描述: | IC THERMO COOLER CNTRLR 32-LFCSP |
| 标准包装: | 1 |
| 应用: | 热电冷却器 |
| 电流 - 电源: | 8mA |
| 电源电压: | 3.3 V ~ 5 V |
| 工作温度: | -40°C ~ 85°C |
| 安装类型: | 表面贴装 |
| 封装/外壳: | 32-VFQFN 裸露焊盘,CSP |
| 供应商设备封装: | 32-LFCSP-VQ(5x5) |
| 包装: | 剪切带 (CT) |
| 其它名称: | ADN8830ACPZ-REELCT |
��
�
�ADN8830�
�response� of� the� TEC’s� temperature� either� in� terms� of� settling� time�
�or� maximum� current� change.� Details� of� how� to� adjust� the� compen-�
�sation� network� are� given� in� the� Compensation� Loop� section.�
�The� ADN8830� can� be� easily� integrated� with� a� wavelength� locker�
�for� fine-tune� temperature� adjustment� of� the� laser� diode� for� a�
�specific� wavelength.� This� is� a� useful� topology� for� tunable� wave-�
�length� lasers.� Details� are� highlighted� in� the� Using� the� TEC�
�Controller� ADN8830� with� a� Wave� Locker� section.�
�The� TEC� is� driven� differentially� using� an� H-bridge� configura-�
�tion� to� maximize� the� output� voltage� swing.� The� ADN8830�
�drives� external� transistors� that� are� used� to� provide� current� to� the�
�TEC.� These� transistors� can� be� selected� by� the� user� based� on� the�
�simple� integrator� or� PID� loop,� the� dc� forward� gain� of� the�
�compensation� section� is� equal� to� the� open-loop� gain� of� the�
�compensation� amplifier,� which� is� over� 80� dB� or� 10,000.� The�
�output� from� the� compensation� loop� at� COMPOUT� is� then� fed�
�to� the� linear� amplifier.� The� output� of� the� linear� amplifier� at�
�OUT� B� is� fed� with� COMPOUT� into� the� PWM� amplifier� whose�
�output� is� OUT� A.� These� two� outputs� provide� the� voltage� drive�
�directly� to� the� TEC.� Including� the� external� transistors,� the� gain� of�
�the� differential� output� section� is� fixed� at� 4.� Details� on� the� output�
�amplifiers� can� be� found� in� the� Output� Driver� Amplifiers� section.�
�1.5V�
�maximum� output� current� required� for� the� TEC.� The� maximum�
�voltage� across� the� TEC� can� be� set� through� use� of� the� VLIM� pin�
�on� the� ADN8830.�
�To� further� improve� the� power� efficiency� of� the� system,� one� side�
�TEMPSET�
�THERMIN�
�4�
�2�
�INPUT�
�AMPLIFIER�
�1.5V�
�A� V� =� 20�
�COMPENSATION� PWM/LINEAR�
�AMPLIFIER� AMPLIFIERS�
�19�
�9�
�OUT� A�
�OUT� B�
�of� the� H-bridge� uses� a� switched� output.� Only� one� inductor� and�
�A� V� =� Z2/Z1�
�A� V� =� 4�
�one� capacitor� are� required� to� filter� out� the� switching� frequency.�
�The� output� voltage� ripple� is� a� function� of� the� output� inductor�
�12�
�TEMPCTL�
�Z1�
�13�
�Z2�
�14�
�COMPOUT�
�and� capacitor� and� the� switching� frequency.� For� most� applica-�
�tions,� a� 4.7� μ� H� inductor,� 22� μ� F� capacitor,� and� switching� frequency�
�of� 1� MHz� maintains� less� than� ±� 0.5%� worst-case� output� voltage�
�ripple� across� the� TEC.� The� other� side� of� the� H-bridge� does� not�
�require� any� additional� circuitry.�
�The� oscillator� section� of� the� ADN8830� controls� the� switched�
�output� section.� A� single� resistor� sets� the� switching� frequency�
�from� 100� kHz� to� 1� MHz.� The� clock� output� is� available� at� the�
�SYNCOUT� pin� and� can� be� used� to� drive� another� ADN8830�
�device� by� connecting� to� its� SYNCIN� pin.� The� phase� of� the�
�clock� is� adjusted� by� a� voltage� applied� to� the� PHASE� pin,� which�
�can� be� set� by� a� simple� resistor� divider.� Phase� adjustment� allows�
�two� or� more� ADN8830� devices� to� operate� from� the� same� clock�
�frequency� and� not� have� all� outputs� switch� simultaneously,� which�
�could� create� an� excessive� power� supply� ripple.� Details� of� how� to�
�adjust� the� clock� frequency� and� phase� are� given� in� the� Setting� the�
�Switching� Frequency� section.�
�For� effective� indication� of� a� catastrophic� system� failure,� the�
�ADN8830� alerts� to� open-circuit� or� short-circuit� conditions� from� the�
�COMPFB�
�Figure� 2.� Signal� Flow� Block� Diagram� of� the� ADN8830�
�Thermistor� Setup�
�The� temperature� of� the� thermal� object,� such� as� a� laser� diode,� is�
�detected� with� a� negative� temperature� coefficient� (NTC)� thermistor.�
�The� thermistor’s� resistance� exhibits� an� exponential� relationship� to�
�the� inverse� of� temperature,� meaning� the� resistance� decreases� at�
�higher� temperatures.� Thus,� by� measuring� the� thermistor� resistance,�
�temperature� can� be� ascertained.� Betatherm� is� a� leading� supplier�
�of� NTC� thermistors.� Thermistor� information� and� details� can� be�
�found� at� www.betatherm.com.�
�For� this� application,� the� resistance� is� measured� using� a� voltage�
�divider.� The� thermistor� is� connected� between� THERMIN� (Pin� 2)�
�and� AGND� (Pin� 30).� Another� resistor� (R� X� )� is� connected� between�
�VREF� (Pin� 7)� and� THERMIN� (Pin� 2),� creating� a� voltage� divider�
�for� the� VREF� voltage.� Figure� 3� shows� the� schematic� for� this�
�configuration.�
�V� DD�
�thermistor,� preventing� an� erroneous� and� potentially� damaging�
�temperature� correction� from� occurring.� With� some� additional�
�external� circuitry,� output� overcurrent� detection� can� be� imple-�
�mented� to� provide� warning� in� the� event� of� a� TEC� short-circuit�
�failure.� This� circuit� is� highlighted� in� the� Setting� Maximum�
�Output� Current� and� Short-Circuit� Protection� section.�
�Signal� Flow� Diagram�
�Figure� 2� shows� the� signal� flow� diagram� through� the� ADN8830.�
�R� X�
�R� THERM�
�7�
�2�
�8�
�ADN8830�
�TEMPCTL� =� 20� ×� (� TEMPSET� –� THERMIN� )� +� 1� .� 5�
�The input amplifier is fixed with a gain of 20. The voltage at�
�TEMPCTL� can� be� expressed� as�
�(1)�
�When� the� temperature� is� settled,� the� thermistor� voltage� will� be�
�equal� to� the� TEMPSET� voltage,� and� the� output� of� the� input�
�amplifier� will� be� 1.5� V.�
�The� voltage� at� TEMPCTL� is� then� fed� into� the� compensation�
�amplifier� whose� frequency� response� is� dictated� by� the� compen-�
�sation� network.� Details� on� the� compensation� amplifier� can� be�
�found� in� the� Compensation� Loop� section.� When� configured� as� a�
�–8� –�
�30�
�Figure� 3.� Connecting� a� Thermistor� to� the� ADN8830�
�With� the� thermistor� connected� from� THERMIN� to� AGND,� the�
�voltage� at� THERMIN� will� decrease� as� temperature� increases.�
�To� maintain� the� proper� input-to-output� polarity� in� this� configu-�
�ration,� OUT� A� (Pin� 19)� should� connect� to� the� TEC–� pin� on� the�
�TEC,� and� OUT� B� (Pin� 9)� should� connect� to� the� VTEC+� pin.�
�The� thermistor� can� also� be� connected� from� VREF� to� THERMIN�
�with� R� X� connecting� to� ground.� In� this� case,� OUT� A� must� connect� to�
�TEC+� with� OUT� B� connected� to� TEC–� for� proper� operation.�
�REV.� D�
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