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参数资料
| 型号: | HSP50214BVIZ |
| 厂商: | Intersil |
| 文件页数: | 9/62页 |
| 文件大小: | 0K |
| 描述: | IC DOWNCONVERTER 14BIT 120-MQFP |
| 标准包装: | 24 |
| 功能: | 降频器 |
| RF 型: | AMPS,CDMA,GSM,TDMA |
| 封装/外壳: | 120-BQFP |
| 包装: | 托盘 |
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�HSP50214B�
�14-Bit� Input� and� Processing� Resolution�
�The� PDC� maintains� a� minimum� of� 14-bits� of� processing�
�resolution� through� to� the� output,� providing� over� 84dB� of�
�dynamic� range.� The� 18-bits� of� resolution� on� the� internal�
�references� provide� a� spurious� floor� that� is� better� than� 98dBc.�
�Furthermore,� the� PDC� provides� up� to� 42dB� of� gain� scaling� to�
�compensate� for� any� change� in� gain� in� the� RF� front� end� as�
�well� as� up� to� 96dB� of� gain� in� the� internal� PDC� AGC.� This�
�gain� maximizes� the� output� resolution� for� small� signals� and�
�compensates� for� changes� in� the� RF� front� end� gain,� to� handle�
�changes� in� the� incoming� signal.�
�Summary�
�The� greatest� feature� of� the� PDC� is� its� ability� to� be�
�reconfigured� to� process� many� common� standards� in� the�
�communications� industry.� Thus,� a� single� hardware� element�
�can� receive� and� process� a� wide� variety� of� signals� from� PCS�
�to� traditional� cellular,� from� wireless� local� loop� to� SATCOM.�
�The� high� resolution� frequency� tuning� and� narrowband�
�filtering� are� instrumental� in� almost� all� of� the� applications.�
�Multiple� Chip� Synchronization�
�Multiple� PDCs� are� synchronized� using� a� MASTER/SLAVE�
�configuration.� One� part� is� responsible� for� synchronizing� the�
�front� end� internal� circuitry� using� CLKIN� while� another� part� is�
�responsible� for� synchronizing� the� backend� internal� circuitry�
�using� PROCCLK.�
�The� PDC� is� synchronized� with� other� PDCs� using� five� control�
�lines:� SYNCOUT,� SYNCIN1,� SYNCIN2,� MSYNCO,� and�
�MSYNCI.� Figure� 2� shows� the� interconnection� of� these� five�
�signals� for� multiple� chip� synchronization� where� different�
�sources� are� used� for� CLKIN� and� PROCCLK.�
�PDC� A� is� the� Master� sync� through� MSO.�
�PDC� B� configures� the� CLKIN� sync� through� SYNCIN1.�
�PDC� A� configures� the� PROCCLK� sync� through� SYNCIN2.�
�the� carrier� NCO� and/or� the� 5th� order� CIC� filter� of� all� PDCs� can�
�be� synchronously� loaded� /� updated� using� SYNCIN1.� See�
�Control� Word� 0,� Bits� 19� and� 20� in� the� Microprocessor� Write�
�Section� for� details.�
�SYNCOUT� for� one� of� the� PDC’s� other� than� PDC� B,� should�
�be� set� for� PROCCLK� (bit� 3� =� 1� in� Control� Word� 0).� This�
�output� signal� is� tied� to� the� SYNCIN2� of� all� PDCs.� The�
�SYNCIN2� can� be� programmed� so� that� the� AGC� updates� its�
�accumulator� with� the� contents� in� the� master� registers�
�(Control� Word� 8,� Bit� 29� in� the� Microprocessor� Write� Section).�
�SYNCIN2� is� also� used� to� load� or� reset� the� timing� NCO� using�
�bit� 5,� Control� Word� 11.� The� halfband� and� FIR� filters� can� be�
�reset� on� SYNCIN2� using� Control� Word� 7,� Bit� 21.� The�
�MSYNCO� of� one� of� the� PDCs� is� then� used� to� drive� the�
�MSYNCI� of� all� the� PDCs� (including� its� own).�
�For� application� configurations� where� CLKIN� and� PROCCLK�
�have� the� same� source,� SYNCIN1� and� SYNCIN2� can� be� tied�
�together.� However,� if� different� enabling� is� desired� for� the�
�front� end� and� backend� processing� of� the� PDC’s,� these�
�signals� can� still� be� controlled� independently.�
�In� the� HSP50214B,� the� Control� Word� 25� reset� signal� has�
�been� extended� so� that� the� front� end� reset� is� 10� CLKIN�
�periods� wide� and� the� back� end� reset� is� 10� PROCCLK�
�periods� wide.� This� guarantees� that� no� enables� will� be� caught�
�in� the� pipelines.� In� addition,� the� SYNCIN1� internal� reset�
�signal,� which� is� enabled� by� setting� Control� Word� 7,�
�Bit� 21� =� 1,� has� been� extended� to� 10� cycles.�
�In� summary,� SYNCIN1� is� used� to� update� carrier� phase�
�offset,� update� carrier� center� frequency,� reset� CIC� decimation�
�counters� and� reset� the� carrier� NCO� (clear� the� feedback� in�
�the� NCO).� SYNCIN2� is� used� to� reset� the� HB� filter,� FIR� filter,�
�re-sampler� /� HB� state� machines� and� the� output� FIFO,� load� a�
�new� gain� into� the� AGC� and� load� a� new� re-sampler� NCO�
�center� frequency� and� phase� offset.�
�A�
�HSP50214B�
�MSYNCO�
�MSYNCI�
�B�
�HSP50214B�
�MSYNCO�
�MSYNCI�
�Input� Section�
�The� block� diagram� of� the� input� controller� is� provided� in�
�Figure� 3.� The� input� can� support� offset� binary� or� two’s�
�complement� data� and� can� be� operated� in� gated� or�
�interpolated� mode� (see� Control� Word� 0� from� the�
�(MASTER�
�SYNCIN2)�
�SYNCOUT�
�SYNCIN2�
�SYNCIN1�
�SYNCOUT�
�SYNCIN2�
�SYNCIN1�
�(MASTER�
�SYNCIN1)�
�Microprocessor� Write� Section).� The� gated� mode� takes� one�
�sample� per� clock� when� the� input� enable� (ENI)� is� asserted.�
�The� gated� mode� allows� the� user� to� synchronize� a� low� speed�
�sampling� clock� to� a� high� speed� CLKIN.�
�ALL� OTHER� SYNCIN1�
�ALL� OTHER� SYNCIN2�
�ALL� OTHER� MSI�
�FIGURE� 2.� SYNCHRONIZATION� CIRCUIT�
�SYNCOUT� for� PDC� B� should� be� set� to� be� synchronous� with�
�CLKIN� (Control� Word� 0,� Bit� 3� =� 0.� See� the� Microprocessor�
�Write� Section).� SYNCOUT� for� PDC� B� is� tied� to� the� SYNCIN1�
�of� all� the� PDCs.� The� SYNCIN1� can� be� programmed� so� that�
�9�
�The� interpolated� mode� allows� the� user� to� input� data� at� a� low�
�sample� rate� and� to� zero-stuff� the� data� prior� to� filtering.� This�
�zero� stuffing� effectively� interpolates� the� input� signal� up� to� the�
�rate� of� the� input� clock� (CLKIN).� This� interpolated� mode�
�allows� the� part� to� be� used� at� rates� where� the� sampling�
�frequency� is� above� the� maximum� input� rate� range� of� the�
�halfband� filter� section,� and� where� the� desired� output�
�bandwidth� is� too� wide� to� use� a� Cascaded� Integrator� Comb�
�(CIC)� filter� without� significantly� reducing� the� dynamic� range.�
�FN4450.4�
�May� 1,� 2007�
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相关代理商/技术参数 |
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| HSP50214VC | 制造商:Rochester Electronics LLC 功能描述:- Bulk |
| HSP50214VI | 制造商:Rochester Electronics LLC 功能描述:- Bulk |
| HSP50215 | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:DSP Modulator Evaluation Board |
| HSP50215EVAL | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:DSP Modulator Evaluation Board |
| HSP50215VC | 制造商:INTERSIL 制造商全称:Intersil Corporation 功能描述:Digital UpConverter |
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