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参数资料
| 型号: | MICRF022YM-FS48 |
| 厂商: | Micrel Inc |
| 文件页数: | 9/17页 |
| 文件大小: | 0K |
| 描述: | IC RECEIVER ASK 300-440MHZ 8SOIC |
| 标准包装: | 95 |
| 频率: | 300MHz ~ 440MHz |
| 灵敏度: | -97dBm |
| 数据传输率 - 最大: | 10 kbps |
| 调制或协议: | ASK,OOK |
| 应用: | RKE |
| 电流 - 接收: | 2.2mA |
| 数据接口: | PCB,表面贴装 |
| 天线连接器: | PCB,表面贴装 |
| 电源电压: | 4.75 V ~ 5.5 V |
| 工作温度: | -40°C ~ 85°C |
| 封装/外壳: | 8-SOIC(0.154",3.90mm 宽) |
| 供应商设备封装: | 8-SOIC |
| 包装: | 管件 |
| 产品目录页面: | 571 (CN2011-ZH PDF) |
| 其它名称: | 576-2421 MICRF022YM-FS48-ND |
��
�
�R� SC� =� 145k� ?�
�(4)�
�C� TH� =�
�(5)�
�=�
�(7)�
�Micrel,� Inc.�
�Step� 3:� Selecting� the� C� TH� Capacitor�
�Extraction� of� the� dc� value� of� the� demodulated� signal�
�for� purposes� of� logic-level� data� slicing� is� accomplished�
�using� the� external� threshold� capacitor� C� TH� and� the� on-�
�chip� switched� capacitor� “resistor”� R� SC� ,� shown� in� the�
�block� diagram.�
�Slicing� level� time� constant� values� vary� somewhat� with�
�decoder� type,� data� pattern,� and� data� rate,� but� typically�
�values� range� from� 5ms� to� 50ms.� Optimization� of� the�
�value� of� C� TH� is� required� to� maximize� range.�
�Selecting� Capacitor� C� TH�
�The� first� step� in� the� process� is� selection� of� a� data-slicing-�
�level� time� constant.� This� selection� is� strongly� dependent� on�
�system� issues� including� system� decode� response� time� and�
�data� code� structure� (that� is,� existence� of� data� preamble,�
�etc.).� This� issue� is� covered� in� more� detail� in� Application�
�Note� 22.�
�The� effective� resistance� of� R� SC� is� listed� in� the� electrical�
�characteristics� table� as� 145k� ?� at� 315MHz,� this� value� scales�
�linearly� with� frequency.� Source� impedance� of� the� C� TH� pin� at�
�other� frequencies� is� given� by� Equation� 4,� where� f� T� is� in�
�MHz:�
�4.8970�
�f� T�
�τ� of� 5x� the� bit-rate� is� recommended.� Assuming� that� a� slicing�
�level� time� constant� τ� has� been� established,� capacitor� C� TH�
�may� be� computed� using� Equation� 5:�
�τ�
�R� SC�
�A� standard� ±20%� X7R� ceramic� capacitor� is� generally�
�sufficient.� Refer� to� Application� Hint� 42� for� C� TH� and� CAGC�
�selection� examples.�
�Step� 4:� Selecting� the� C� AGC� Capacitor�
�The� signal� path� has� AGC� (automatic� gain� control)� to�
�increase� input� dynamic� range.� The� attack� time� constant� of�
�the� AGC� is� set� externally� by� the� value� of� the� C� AGC� capacitor�
�connected� to� the� C� AGC� pin� of� the� device.� To� maximize�
�system� range,� it� is� important� to� keep� the� AGC� control�
�voltage� ripple� low,� preferably� under� 10mV� PP� once� the�
�control� voltage� has� attained� its� quiescent� value.� For� this�
�reason� capacitor� values� of� at� least� 0.47� μ� F� are�
�recommended.�
�The� AGC� control� voltage� is� carefully� managed� on-chip� to�
�allow� duty-cycle� operation� of� the� MICRF002.� When� the�
�device� is� placed� into� shutdown� mode� (SHUT� pin� pulled�
�high),� the� AGC� capacitor� floats� to� retain� the� voltage.� When�
�operation� is� resumed,� only� the� voltage� droop� due� to�
�capacitor� leakage� must� be� replenished.� A� relatively� low-�
�leakage� capacitor� is� recommended� when� the� devices� are�
�used� in� dutycycled� operation.�
�MICRF002/RF022�
�To� further� enhance� duty-cycled� operation,� the� AGC� push�
�and� pull� currents� are� boosted� for� approximately� 10ms�
�immediately� after� the� device� is� taken� out� of� shutdown.� This�
�compensates� for� AGC� capacitor� voltage� droop� and� reduces�
�the� time� to� restore� the� correct� AGC� voltage.� The� current� is�
�boosted� by� a� factor� of� 45.�
�Selecting� C� AGC� Capacitor� in� Continuous� Mode�
�A� C� AGC� capacitor� in� the� range� of� 0.47� μ� F� to� 4.7� μ� F� is� typically�
�recommended.� The� value� of� the� C� AGC� should� be� selected� to�
�minimize� the� ripple� on� the� AGC� control� voltage� by� using� a�
�sufficiently� large� capacitor.� However� if� the� capacitor� is� too�
�large� the� AGC� may� react� too� slowly� to� incoming� signals.�
�AGC� settling� time� from� a� completely� discharged� (zero-volt)�
�state� is� given� approximately� by� Equation� 6:�
�(6)� ?� t� =� 1.333C� AGC� ?� 0.44�
�where:�
�C� AGC� sin� in� μ� F,� and� ?� t� is� in� seconds.�
�Selecting� C� AGC� Capacitor� in� Duty-Cycle� Mode�
�Voltage� droop� across� the� C� AGC� capacitor� during� shutdown�
�should� be� replenished� as� quickly� as� possible� after� the� IC� is�
�enabled.� As� mentioned� above,� the� MICRF002� boosts� the�
�push-pull� current� by� a� factor� of� 45� immediately� after� start-�
�up.� This� fixed� time� period� is� based� on� the� reference�
�oscillator� frequency� f� T� .� The� time� is� 10.9ms� for� f� T� =� 6.00MHz,�
�and� varies� inversely� with� f� T� .� The� value� of� C� AGC� capacitor�
�and� the� duration� of� the� shutdown� time� period� should� be�
�selected� such� that� the� droop� can� be� replenished� within� this�
�10ms� period.�
�Polarity� of� the� droop� is� unknown,� meaning� the� AGC� voltage�
�could� droop� up� or� down.� Worst-case� from� a� recovery�
�standpoint� is� downward� droop,� since� the� AGC� pull-up�
�current� is� 1/10th� magnitude� of� the� pulldown� current.� The�
�downward� droop� is� replenished� according� to� the� Equation�
�7:�
�I� ?� V�
�C� AGC� ?� t�
�where:�
�I� =� AGC� pullup� current� for� the� initial� 10ms� (67.5� μ� A)�
�C� AGC� =� AGC� capacitor� value�
�?� t� =� droop� recovery� time�
�?� V� =� droop� voltage�
�For� example,� if� user� desires� ?� t� =� 10ms� and� chooses� a�
�4.7� μ� F� C� AGC� ,� then� the� allowable� droop� is� about� 144mV.�
�Using� the� same� equation� with� 200nA� worst� case� pin�
�leakage� and� assuming� 1� μ� A� of� capacitor� leakage� in� the�
�same� direction,� the� maximum� allowable� ?� t� (shutdown� time)�
�is� about� 0.56s� for� droop� recovery� in� 10ms.�
�The� ratio� of� decay-to-attack� time-constant� is� fixed� at� 10:1�
�(that� is,� the� attack� time� constant� is� 1/10th� of� the� decay� time�
�constant).� Generally� the� design� value� of� 10:1� is� adequate�
�July� 2008�
�9�
�M9999-070808�
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| MICRF022YM-FS48 TR | 功能描述:射频接收器 300-440MHz RF Receiver With Shutdown( Lead Free) RoHS:否 制造商:Skyworks Solutions, Inc. 类型:GPS Receiver 封装 / 箱体:QFN-24 工作频率:4.092 MHz 工作电源电压:3.3 V 封装:Reel |
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