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PERFORMANCE� CHARACTERISTICS� OF� EPAD?�
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PRECISION� MATCHED� PAIR� MOSFET� FAMILY� (cont.)�
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SUB-THRESHOLD� REGION� OF� OPERATION�
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Low� voltage� systems,� namely� those� operating� at� 5V,� 3.3V� or� less,�
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typically� require� MOSFETs� that� have� threshold� voltage� of� 1V� or�
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less.� The� threshold,� or� turn-on,� voltage� of� the� MOSFET� is� a� voltage�
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below� which� the� MOSFET� conduction� channel� rapidly� turns� off.� For�
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analog� designs,� this� threshold� voltage� directly� affects� the� operating�
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signal� voltage� range� and� the� operating� bias� current� levels.�
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At� or� below� threshold� voltage,� an� EPAD� MOSFET� exhibits� a� turn-�
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off� characteristic� in� an� operating� region� called� the� subthreshold� re-�
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gion.� This� is� when� the� EPAD� MOSFET� conduction� channel� rapidly�
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turns� off� as� a� function� of� decreasing� applied� gate� voltage.� The� con-�
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duction� channel� induced� by� the� gate� voltage� on� the� gate� electrode�
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decreases� exponentially� and� causes� the� drain� current� to� decrease�
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exponentially.� However,� the� conduction� channel� does� not� shut� off�
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abruptly� with� decreasing� gate� voltage,� but� decreases� at� a� fixed� rate�
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of� approximately� 116mV� per� decade� of� drain� current� decrease.� Thus�
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if� the� threshold� voltage� is� +0.20V,� for� example,� the� drain� current� is�
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1uA� at� V� GS� =� +0.20V.� At� V� GS� =� +0.09V,� the� drain� current� would�
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decrease� to� 0.1uA.� Extrapolating� from� this,� the� drain� current� is�
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0.01uA� (10nA)� at� V� GS� =� -0.03V,� 1nA� at� V� GS� =� -0.14V,� and� so� forth.�
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This� subthreshold� characteristic� extends� all� the� way� down� to� cur-�
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ZERO� TEMPERATURE� COEFFICIENT� (ZTC)� OPERATION�
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For� an� EPAD� MOSFET� in� this� product� family,� there� exist� operating�
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points� where� the� various� factors� that� cause� the� current� to� increase�
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as� a� function� of� temperature� balance� out� those� that� cause� the� cur-�
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rent� to� decrease,� thereby� canceling� each� other,� and� resulting� in� net�
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temperature� coefficient� of� near� zero.� One� of� this� temperature� stable�
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operating� point� is� obtained� by� a� ZTC� voltage� bias� condition,� which�
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is� 0.55V� above� a� threshold� voltage� when� V� GS� =� V� DS� ,� resulting� in� a�
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temperature� stable� current� level� of� about� 68uA.� For� other� ZTC� op-�
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erating� points,� see� ZTC� characteristics.�
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PERFORMANCE� CHARACTERISTICS�
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Performance� characteristics� of� the� EPAD� MOSFET� product� family�
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are� shown� in� the� following� graphs.� In� general,� the� threshold� voltage�
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shift� for� each� member� of� the� product� family� causes� other� affected�
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electrical� characteristics� to� shift� with� an� equivalent� linear� shift� in�
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V� GS(th)� bias� voltage.� This� linear� shift� in� V� GS� causes� the� subthresh-�
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old� I-V� curves� to� shift� linearly� as� well.� Accordingly,� the� subthreshold�
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operating� current� can� be� determined� by� calculating� the� gate� volt-�
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age� drop� relative� from� its� threshold� voltage,� V� GS(th)� .�
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rent� levels� below� 1nA� and� is� limited� by� other� currents� such� as� junc-�
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tion� leakage� currents.�
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RDS(ON)� AT� VGS=GROUND�
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At� a� drain� current� to� be� declared� “zero� current”� by� the� user,� the� Vgs�
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voltage� at� that� zero� current� can� now� be� estimated.� Note� that� using�
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the� above� example,� with� V� GS(th)� =� +0.20V,� the� drain� current� still�
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hovers� around� 20nA� when� the� gate� is� at� zero� volt,� or� ground.�
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LOW� POWER� AND� NANOPOWER�
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When� supply� voltages� decrease,� the� power� consumption� of� a� given�
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load� resistor� decreases� as� the� square� of� the� supply� voltage.� So�
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one� of� the� benefits� in� reducing� supply� voltage� is� to� reduce� power�
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consumption.� While� decreasing� power� supply� voltages� and� power�
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consumption� go� hand-in-hand� with� decreasing� useful� AC� bandwidth�
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and� at� the� same� time� increases� noise� effects� in� the� circuit,� a� circuit�
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designer� can� make� the� necessary� tradeoffs� and� adjustments� in� any�
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given� circuit� design� and� bias� the� circuit� accordingly.�
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With� EPAD� MOSFETs,� a� circuit� that� performs� a� specific� function�
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can� be� designed� so� that� power� consumption� can� be� minimized.� In�
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some� cases,� these� circuits� operate� in� low� power� mode� where� the�
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power� consumed� is� measure� in� micro-watts.� In� other� cases,� power�
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dissipation� can� be� reduced� to� nano-watt� region� and� still� provide� a�
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useful� and� controlled� circuit� function� operation.�
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Several� of� the� EPAD� MOSFETs� produce� a� fixed� resistance� when�
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their� gate� is� grounded.� For� ALD110800,� the� drain� current� at� V� DS� =�
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0.1V� is� at� 1uA� at� V� GS� =� 0.0V.� Thus� just� by� grounding� the� gate� of� the�
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ALD110800,� a� resistor� with� R� DS(ON)� =� ~100KOhm� is� produced.�
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When� an� ALD114804� gate� is� grounded,� the� drain� current� I� DS� =� 18.5�
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uA@� V� DS� =� 0.1V,� producing� R� DS(ON)� =� 5.4KOhm.� Similarly,�
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ALD114813� and� ALD114835� produces� 77uA� and� 185uA,� respec-�
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tively,� at� V� GS� =� 0.0V,� producing� R� DS(ON)� values� of� 1.3KOhm� and�
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540Ohm,� respectively.�
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MATCHING� CHARACTERISTICS�
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A� key� benefit� of� using� matched-pair� EPAD� MOSFET� is� to� maintain�
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temperature� tracking.� In� general,� for� EPAD� MOSFET� matched� pair�
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devices,� one� device� of� the� matched� pair� has� gate� leakage� currents,�
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junction� temperature� effects,� and� drain� current� temperature� coeffi-�
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cient� as� a� function� of� bias� voltage� that� cancel� out� similar� effects� of�
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the� other� device,� resulting� in� a� temperature� stable� circuit.� As� men-�
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tioned� earlier,� this� temperature� stability� can� be� further� enhanced� by�
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biasing� the� matched-pairs� at� Zero� Tempco� (ZTC)� point,� even� though�
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that� could� require� special� circuit� configuration� and� power� consump-�
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tion� design� consideration.�
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ALD114835/ALD114935�
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Advanced� Linear� Devices�
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4� of� 11�
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