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参数资料
| 型号: | ADN8830ACPZ-REEL |
| 厂商: | Analog Devices Inc |
| 文件页数: | 19/22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�
�=� C� 1� � R� 1�
�Power Supply Ripple�
�Minimizing� ripple� on� the� power� supply� voltage� can� be� an� impor-�
�tant� consideration,� particularly� in� signal� source� laser� applications.�
�If� the� laser� diode� is� operated� from� the� same� supply� rail� as� the� TEC�
�controller,� ripple� on� the� supply� voltage� could� cause� inadvertent�
�modulation� of� the� laser� frequency.� As� most� laser� diodes� are� driven�
�from� a� 5� V� supply,� it� is� recommended� the� ADN8830� be� operated�
�from� a� separate� 3.3� V� regulated� supply� unless� higher� TEC� voltages�
�are� required.� Operation� from� 3.3� V� also� improves� efficiency,� thus�
�minimizing� power� dissipation.�
�The� power� supply� ripple� is� primarily� a� function� of� the� supply� by-�
�pass� capacitance,� also� called� bulk� capacitance,� and� the� inductor�
�ripple� current.� Similar� to� the� L-C� filter� at� the� PWM� amplifier�
�output,� using� more� capacitance� with� low� equivalent� series� resis-�
�tance� (ESR)� will� lower� the� supply� ripple.� A� larger� inductor� value�
�will� reduce� the� inductor� ripple� current,� but� this� may� not� be�
�practical� in� the� application.� A� recommended� approach� is� to� use� a�
�standard� electrolytic� capacitor� in� parallel� with� a� low� ESR� capacitor.�
�A� surface-mount� 220� μ� F� electrolytic� in� parallel� with� a� 22� μ� F� poly-�
�mer� aluminum� low� ESR� capacitor� can� occupy� an� approximate� total�
�board� area� of� only� 0.94� square� inches� or� 61� square� millimeters.�
�Using� these� capacitors� along� with� a� 4.7� μ� H� inductor� can� yield� a�
�supply� ripple� of� less� than� 5� mV.�
�A� 10� m� Ω� resistor� placed� in� series� with� the� PVDD� supply� line� creates� a�
�voltage� drop� proportional� to� the� absolute� value� of� the� output� current.�
�The� AD8601� is� a� CMOS� amplifier� that� is� configured� as� a� com-�
�parator.� As� long� as� the� voltage� at� its� inverting� input� (V� S� )� exceeds�
�the� voltage� set� by� the� resistor� divider� at� the� noninverting� input� (V� X� ),�
�the� gate� of� Q1� will� remain� at� ground.� This� leaves� Q1� on,� effectively�
�connecting� D1� to� the� positive� rail� and� leaving� the� voltage� on� C1� at�
�V� DD� .� Should� enough� current� flow� through� R� S� to� drop� V� S� below� V� X� ,�
�Q1� will� turn� off� and� C1� will� discharge� through� R2� down� to� a� logic�
�low� to� activate� the� ADN8830� shutdown.� Once� V� S� returns� to� a�
�voltage� greater� than� V� X� ,� Q1� will� turn� back� on� and� C1� will� charge�
�back� to� V� DD� through� R1.� The� shutdown� and� reactivation� time�
�constants� are� approximately�
�SD� =� C� 1� � R� 1�
�(42)�
�ON�
�The� shutdown� time� constant� should� be� a� minimum� of� 10� clock�
�cycles� to� ensure� high� current� switching� transients� do� not� trigger� a�
�false� activation.� If� powered� from� 5� V,� the� circuit� shown� will� shut�
�down� the� ADN8830� should� PVDD� deliver� over� 5� A� for� more� than�
�1� ms.� After� shutdown,� the� circuit� will� reactivate� the� ADN8830� in�
�about� 1� second.�
�The� voltage� drop� across� R� S� is� found� as�
�I� OUT� L� S�
�R� R�
�High� frequency� transient� spikes� may� appear� on� the� supply� voltage�
�as� well.� This� is� due� to� the� fast� switching� times� on� the� PWM� transis-�
�tors� and� the� sharp� edges� of� their� gate� voltages.� Although� these�
�V� R� S� =�
�2�
�η� V� DD�
�(43)�
�transient� spikes� can� reach� several� tens� of� millivolts� at� their� peak,�
�where� R� L� is� the� load� resistance� or� resistance� of� the� TEC� and�
�is�
�they� typically� last� for� less� than� 20� ns� and� have� a� resonance� greater�
�than� 100� MHz.� Additional� bulk� capacitance� will� not� appreciably�
�the� efficiency� of� the� system.� An� estimate� of� efficiency� can� be� calculated�
�either� from� the� Calculating� Power� Dissipation� and� Efficiency� section�
�affect� the� level� of� these� spikes� as� such� capacitance� is� not� reactive� at�
�or� from� Figures� 16� and� 17.� A� reasonable� approximation� is�
�=�
�these� frequencies.� Adding� 0.01� μ� F� ceramic� capacitors� on� the� sup-�
�ply� line� near� the� PWM� PMOS� transistor� can� reduce� this� switching�
�noise.� Inserting� an� RF� inductor� with� a� High-Q� around� 100� MHz� in�
�series� with� PVDD� will� also� block� this� noise� from� traveling� back� to�
�the� power� supply.�
�Setting� Maximum� Output� Current� and� Short-Circuit�
�Protection�
�Although� the� maximum� output� voltage� can� be� programmed�
�through� VLIM� to� protect� the� TEC� from� overvoltage� damage,�
�the� user� may� wish� to� protect� the� ADN8830� circuit� from� a� possible�
�short� circuit� at� the� output.� Such� a� short� could� quickly� damage� the�
�external� FETs� or� even� the� power� supply� since� they� would� attempt�
�to� drive� excessive� current.� Figure� 20� shows� a� simple� modification�
�that� will� protect� the� system� from� an� output� short� circuit.�
�0.85.� Although� the� exact� resistance� of� a� TEC� varies� with� tempera-�
�ture,� an� estimation� can� be� made� by� dividing� the� maximum� voltage�
�rating� of� the� TEC� by� its� maximum� current� rating.�
�In� addition� to� providing� protection� against� a� short� at� the� output,�
�this� circuit� will� also� protect� the� FETs� against� shoot-through� current.�
�Shoot-through� will� not� occur� when� using� the� recommended�
�transistors� and� additional� capacitance� shown� in� Tables� V� and� VI.�
�However,� if� different� transistors� are� used� where� their� shoot-�
�through� potential� is� unknown,� implementing� the� short-circuit�
�protection� circuit� will� unconditionally� protect� these� transistors.�
�To� set� a� maximum� output� current� limit,� use� the� circuit� in� Figure�
�21.� This� circuit� can� share� the� 10� m� Ω� power� supply� shunt� resistor�
�as� the� short-circuit� protection� circuit� to� sense� the� output� current.�
�In� normal� operation� Q1� is� on,� pulling� the� ADN8830� VLIM� pin�
�TO�
�V� S�
�R� S�
�PVDD�
�AVDD�
�down� to� the� voltage� set� by� VLIMIT.� This� sets� the� maximum� out-�
�put� voltage� limit� as� described� in� the� Setting� the� Maximum� TEC�
�FETS�
�AND�
�DECOUPLING�
�PVDD�
�10m�
�Voltage� and� Current� section.�
�CAPS�
�R3�
�Q1�
�R1�
�TO�
�V� SY�
�R� S�
�PVDD�
�AVDD�
�1k�
�R4�
�100k�
�V� X�
�AD8601�
�R2�
�1k�
�FDV304P�
�OR� EQUIVALENT�
�D1�
�MA116CT-ND�
�OR�
�EQUIVALENT�
�1M�
�C1�
�1� F�
�SD�
�FETS�
�AND�
�DECOUPLING� PVDD�
�CAPS�
�R3�
�178�
�10m�
�R1�
�3.48k�
�AD8605�
�Q1�
�FDV301N�
�OR�
�EQUIVALENT�
�C1�
�1nF�
�TO�
�VLIM�
�R2�
�1.47k�
�R4�
�100k�
�V� X�
�DENOTES�
�AGND�
�DENOTES�
�PGND�
�VLIMIT�
�Figure� 20.� Implementing� Output� Short-Circuit� Protection�
�(0V� TO� 1.5V)�
�DENOTES�
�AGND�
�DENOTES�
�PGND�
�Figure� 21.� Setting� a� Maximum� Output� Current� Limit�
�REV.� D�
�–19� –�
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