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参数资料
| 型号: | MAX2373ETC+T |
| 厂商: | Maxim Integrated |
| 文件页数: | 9/10页 |
| 文件大小: | 0K |
| 描述: | IC AMP LNA STEP ATTEN 12-QFN |
| 产品培训模块: | Lead (SnPb) Finish for COTS Obsolescence Mitigation Program |
| 标准包装: | 2,500 |
| 频率: | 850MHz ~ 940MHz |
| P1dB: | -19.5dBm |
| 增益: | 15.5dB |
| 噪音数据: | 1.8dB |
| RF 型: | 通用 |
| 电源电压: | 2.65 V ~ 3.3 V |
| 电流 - 电源: | 3.5mA |
| 测试频率: | 850MHz ~ 940MHz |
| 封装/外壳: | 12-WFQFN 裸露焊盘 |
| 包装: | 带卷 (TR) |
��
�
�LNAs� with� Step� Attenuator� and� VGA�
�The� MAX2371/MAX2373� can� be� turned� off� in� transmit� or�
�battery-save� standby� mode.� The� receive-enable� pin�
�(RX_EN)� also� can� turn� off� the� devices� even� if� V� CC� is� not�
�removed,� because� multiple� LNAs� can� be� connected� to�
�the� same� V� CC� for� multiband� applications.�
�The� devices� allow� external� matching� networks� to� configure�
�operation� in� a� wide� frequency� range.� Refer� to� the� EV� kit�
�schematic� for� a� guide� to� designing� the� matching� network.�
�Applications� Information�
�AGC�
�The� AGC� of� the� MAX2371/MAX2373� is� controlled� by� an�
�external� voltage� at� pin� AGC.� The� amplifier� is� at� full� gain�
�if� the� voltage� at� pin� AGC� is� nominally� V� CC� /2.� It� is� at� min-�
�imum� gain� if� the� voltage� at� pin� AGC� is� V� CC� .� The� AGC�
�attenuation� range,� which� is� continuously� variable,� is�
�specified� at� 45dB.� The� IP3� will� degrade� slightly� as� AGC�
�reduces� the� gain.�
�The� devices� include� two� gain� modes.� Set� RF_ATTN� high�
�to� enable� the� low-gain� mode,� which� reduces� the� gain� by�
�about� 20dB.� Low-gain� mode� will� increase� the� system� IP3�
�by� approximately� 18dB,� which� provides� strong� signal�
�overload� and� IM� protection.� An� external� pin� (RF_ATTN)�
�controls� switching� between� gain� modes� so� this� function�
�can� be� combined� with� overall� AGC� control.� AGC� is� inde-�
�pendent� of� the� choice� of� gain� mode.� The� gain� step�
�between� modes� is� in� addition� to� the� range� of� AGC,� allow-�
�ing� a� large� overall� gain-control� range.�
�AGC� Response�
�A� linear� transfer� function� between� the� AGC� control� signal�
�and� the� AGC� attenuation� is� realized� in� dB.� The� linear�
�relationship� in� dB/V� is� maintained� to� ±10%� over� a� speci-�
�fied� attenuation� range.� Any� compensation� for� gain-mode�
�change� must� come� from� the� AGC� control.� After� reducing�
�gain� by� switching� the� RF_ATTN� pin,� reduce� the� AGC�
�voltage� to� achieve� the� desired� overall� gain.�
�The� LNA� current� also� can� be� changed� by� toggling� the�
�LNA_I� pin.� This� operation� is� independent� of� gain� mode�
�and� AGC� control.� The� low-current� mode� is� intended� as� a�
�second� (reduced-current)� quiescent� point� of� operation�
�for� strong-signal� operating� environments.�
�Matching� Networks�
�For� best� performance,� match� LNA_IN� and� LNA_OUT� to�
�50� Ω� for� the� band� of� operation.� Typical� matching� circuits�
�for� two� bands� (136MHz� to� 174MHz� and� 850MHz� to�
�940MHz)� are� shown� in� the� EV� kit.� The� chip� impedance�
�changes� minimally� from� low� to� high� gain� and� with� AGC.�
�The� input� requires� a� DC-blocking� capacitor.� The� size� of�
�this� capacitor� influences� the� startup� time� and� IP3.� There�
�is� a� trade-off� between� these:� A� large� DC-blocking�
�capacitor� means� a� good� IP3� and� slow� startup.� The� maxi-�
�mum� startup� time� is� determined� by� the� equation� below:�
�MAXT� START� =� 40� ?� C� AC� ?� R� SET� ,�
�where� C� AC� =� AC-coupling� cap� in� Farads,� R� SET� =� current-�
�setting� resistor� in� Ω� .�
�IP3� will� improve� with� the� separation� of� the� interfering�
�tones,� so� a� wider� channel� system� can� use� a� smaller� DC-�
�blocking� capacitor� and� achieve� a� better� IP3.� The� cus-�
�tomer� also� can� change� the� emitter� inductor� at� LNA_E� to�
�get� the� desired� linearity� and� gain.� Changing� this� induc-�
�tor� value� requires� a� change� to� the� input� match.� The� out-�
�put� is� an� open� collector� and� needs� a� pullup� inductor.� A�
�load� resistor� also� can� be� connected� across� it.� The� resis-�
�tor� determines� the� trade-off� between� the� bandwidth� of�
�the� match� and� the� gain.� A� small� load� resistor� means� a�
�wider� match� and� lower� gain.�
�Layout� Issues�
�For� best� performance,� pay� attention� to� power-supply�
�issues� as� well� as� to� the� layout� of� the� RFOUT� matching�
�network.� The� EV� kit� can� be� used� as� a� layout� example.�
�Ground� connections� followed� by� supply� bypass� are� the�
�most� important.�
�Power-Supply� Bypassing�
�The� MAX2371/MAX2373� have� two� supply� pins:�
�LNA_V� CC� and� RF_V� CC� .� These� must� be� bypassed� sepa-�
�rately.� It� is� assumed� that� there� is� a� large� capacitor�
�decoupling� the� power� supply.� LNA_V� CC� and� RF_V� CC�
�are� each� decoupled� with� 1500pF� (MAX2371)� or� 100pF�
�(MAX2373)� capacitor.� Use� separate� paths� to� the� ground�
�plane� for� each� of� the� bypass� capacitors,� and� minimize�
�trace� length� to� reduce� inductance.� The� exposed� pad�
�must� be� connected� to� system� ground� with� very� low�
�impedance� vias.�
�Power-Supply� Layout�
�To� minimize� coupling� between� sections� of� the� IC,� the�
�ideal� power-supply� layout� is� a� star� configuration� with� a�
�large� decoupling� capacitor� at� a� central� V� CC� node.� The�
�V� CC� traces� branch� from� this� central� node,� each� to� a� sep-�
�arate� V� CC� node� in� the� PC� board.� At� the� end� of� each�
�trace� is� a� bypass� capacitor� that� has� low� ESR� at� the� RF� of�
�operation.� This� arrangement� provides� local� decoupling�
�at� each� V� CC� pin.� At� high� frequencies,� any� signal� leaking�
�out� of� one� supply� pin� sees� a� relatively� high� impedance�
�(formed� by� the� V� CC� trace� inductance)� to� the� central� V� CC�
�node� and� an� even� higher� impedance� to� any� other� supply�
�pin,� as� well� as� a� low� impedance� to� ground� through� the�
�bypass� capacitor.�
�_______________________________________________________________________________________�
�9�
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