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参数资料
| 型号: | ADN8830ACPZ-REEL |
| 厂商: | Analog Devices Inc |
| 文件页数: | 12/22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�
�The� unity-gain� crossover� frequency� of� the� feedforward� amplifier�
�is� given� as�
�f� 0� dB� =�
�1�
�2� π� R� 3� C� 1�
�� 80� � TEC� GAIN�
�(15)�
�0dB�
�R1�
�To� ensure� stability,� the� unity-gain� crossover� frequency� should� be�
�lower� than� the� thermal� time� constant� of� the� TEC� and� thermistor.�
�However,� this� thermal� time� constant� may� not� be� specified� and�
�can� be� difficult� to� characterize.�
�There� are� many� texts� written� on� loop� stabilization,� and� it� is� beyond�
�the� scope� of� this� data� sheet� to� discuss� all� methods� and� trade-offs�
�R2||R3�
�R1�
�R3�
�in� optimizing� compensation� networks.� A� simple� method� that�
�can� be� used� to� empirically� determine� a� PID� compensation� loop�
�1�
�2� R3C1�
�1�
�2� R1C1�
�1�
�2� C2(R2+R3)�
�1�
�2� R2C2�
�as� shown� in� Figure� 9� involves� the� following� procedure:�
�1.� Connect� thermistor� and� TEC� to� the� ADN8830� application�
�circuit.� Power� does� not� need� to� be� applied� to� the� laser� diode�
�for� this� procedure.� Monitor� output� voltage� across� the� TEC�
�with� an� oscilloscope.�
�2.� Short� C1� and� open� C2,� leaving� just� R1� and� R3� as� a� simple�
�proportional-only� compensation� loop.�
�3.� While� maintaining� a� constant� TEMPSET� voltage,� increase�
�the� ratio� of� R1/R3,� thus� increasing� the� gain� until� loop� oscilla-�
�tion� starts� to� occur.� Decrease� this� ratio� by� a� factor� of� 2� from�
�the� point� of� oscillation.� The� R1/R3� ratio� will� likely� be� less�
�than� unity� for� most� laser� modules.�
�4.� Add� C1� capacitor� and� decrease� value� until� oscillation� starts,�
�then� increase� by� a� factor� of� 2.� A� good� initial� starting� value� for�
�C1� is� to� create� a� unity-gain� crossover� of� 0.1� Hz� based� on�
�Equation� 15.�
�5.� Short� R2� and� increase� C2� until� oscillation� starts.� At� this� point,�
�either� C2� can� be� decreased� or� R2� can� be� added� to� regain�
�stability.� Generally� speaking,� R2� will� be� greater� than� R3� and�
�C2� will� be� one� or� more� orders� of� magnitude� less� than� C1.�
�6.� TEMPSET� should� be� adjusted� with� a� step� change� while�
�observing� the� output� voltage� settling� time.� A� step� change� of�
�100� mV� should� suffice.� From� here,� C2,� R2,� and� even� C1� can�
�be� decreased� to� minimize� settling� time� at� the� expense� of�
�additional� output� voltage� overshoot.�
�7.� An� additional� feedback� capacitor,� CF,� in� parallel� with� R1�
�and� C1,� can� be� added� to� add� another� high� frequency� pole.� In�
�many� cases,� this� improves� the� stability� of� the� system� without�
�increasing� the� settling� time� as� out-of-band� noise� is� filtered�
�out� of� the� control� signal.� A� 330� pF� to� 1� nF� capacitor� should�
�FREQUENCY� (Hz� LOG� SCALE)�
�Figure� 10.� Bode� Plot� for� PID� Compensation�
�Using� the� TEC� Controller� ADN8830� with� a� Wave� Locker�
�Many� optical� applications� require� precision� control� of� laser�
�wavelength.� The� wavelength� of� the� laser� diode� can� be� adjusted�
�by� changing� its� temperature,� which� is� done� through� temperature�
�control� of� the� TEC.� Wavelength� control� can� be� done� by� feeding�
�a� wave� locker� or� etalon� output� back� to� the� microprocessor� and�
�using� the� microprocessor� to� calculate� and� reinstruct� the� TEC�
�controller� with� a� new� target� temperature.� However,� this� method�
�is� computationally� expensive� and� has� time� delays� before� the�
�adjustment� is� done.� A� faster� responding� and� simpler� method� is�
�to� feed� the� wave� locker� signal� back� to� the� TEC� controller� for�
�direct� temperature� control.�
�The� ADN8830� is� designed� to� be� compatible� with� a� wave� locker�
�controller.� Figure� 11� shows� the� basic� schematic.� The� TEMPCTL�
�output� from� ADN8830� is� proportional� to� the� object’s� actual�
�temperature.� This� voltage� is� fed� to� the� wave� locker� controller.�
�Also� fed� to� the� wave� locker� controller� are� the� photodiode� out-�
�puts� from� the� wave� locker,� as� well� as� the� laser� diode� power� and�
�a� digital� signal� indicating� a� functional� laser� diode,� both� of� which�
�come� from� the� CW� controller.� The� output� of� the� wave� locker�
�controller� is� then� connected� to� the� input� of� the� compensation�
�network.� This� allows� the� wave� locker� controller� to� adjust� the�
�TEC� temperature� based� on� the� current� temperature� of� the�
�object,� the� current� wavelength� of� the� laser� diode,� and� the� target�
�wavelength.� Once� the� target� wavelength� is� reached,� the� wave�
�locker� controller� sends� a� signal� to� the� microcontroller� indicating�
�that� the� laser� signal� is� good.�
�suffice,� if� required.�
�LOCKER�
�The� typical� values� shown� in� the� typical� application� circuit� in�
�Figure� 1� have� R1� =� 100� k� Ω� ,� R2� =� 1� M� Ω� ,� R3� =� 205� k� Ω� ,� C1� =� 10� μ� F,�
�C2� =� 1� μ� F,� and� an� additional� feedback� capacitor� of� 330� pF.� For�
�most� pump� laser� modules,� this� results� in� a� 10� °� C� TEMPSET� step�
�settling� time� to� within� 0.1� °� C� in� less� than� 5� seconds.�
�ADN8830�
�ADN8830�
�FROM�
�LOCKER�
�FROM� CW�
�CONTROLLER�
�PD1�
�LOCKER�
�PD2�
�WAVE� LOCKER�
�GOOD�
�LASER� DIODE�
�POWER�
�LASER� DIODE�
�GOOD�
�TEC�
�TO�
�MICRO-�
�PROCESSOR�
�REFERENCE�
�CONTROL�
�VOLTAGE�
�COMPOUT�
�COMPFB�
�TEMPCTL�
�COMPOUT�
�12�
�TEMP� IN�
�TEMPCTL�
�COMPFB�
�13�
�14�
�12�
�R3�
�13�
�R1�
�C1�
�14�
�COMPENSATION�
�NETWORK�
�R2�
�C2�
�CF�
�Figure� 9.� Implementing� a� PID� Compensation� Loop�
�–12� –�
�Figure� 11.� Using� the� ADN8830� with� a� Wave� Locker�
�REV.� D�
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