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�MRF89XA�
�3.11.4�
�DC-FREE� DATA� MECHANISMS�
�In� this� case,� the� maximum� chip� rate� is� the� maximum� bit�
�The� payload� to� be� transmitted� may� contain� long�
�sequences� of� ‘� 1� ’s� and� ‘� 0� ’s,� which� introduces� a� DC� bias�
�in� the� transmitted� signal,� which� causes� a� non-uniform�
�power� distribution� spectrum� over� the� occupied� channel�
�bandwidth.� These� sequences� also� degrade� the�
�performance� of� the� demodulation� and� data,� and� clock�
�recovery� functions� in� the� receiver,� which� basically�
�introduces� data� dependencies� in� the� normal� operation�
�of� the� demodulator.� System� performance� can� be�
�enhanced� if� the� payload� bits� are� randomized� to� reduce�
�DC� biases� and� increase� the� number� of� bit� transitions.�
�Therefore,� it� is� useful� if� the� transmitted� data� is� random�
�and� DC-free.�
�To� handle� such� instances,� two� techniques� are� available�
�in� the� packet� handler:� Manchester� encoding� and� Data�
�Whitening.� However,� only� one� of� the� two� methods�
�should� be� enabled� at� a� time.�
�rate� given� in� the� specifications� section� and� the� actual�
�bit� rate� is� half� the� chip� rate.� Manchester� encoding� and�
�decoding� is� only� applied� to� the� payload� and� CRC�
�checksum� while� preamble� and� Sync� word� are� kept�
�NRZ.� However,� the� chip� rate� from� preamble� to� CRC� is�
�the� same� and� defined� by� the� BRVAL<6:0>� bits�
�(BRSREG<6:0>)� (Chip� Rate� =� Bit� Rate� NRZ� =� 2� x� Bit�
�Rate� Manchester).�
�Therefore� Manchester� encoding/decoding� is� made�
�transparent� for� the� user,� who� still� provides/retrieves�
�NRZ� data� to/from� the� FIFO.� See� the� Manchester�
�encoding/decoding� bit� pattern� in� Figure� 3-30� .�
�3.11.4.2� Data� Whitening�
�Another� technique� called� data� whitening� or� scrambling�
�is� widely� used� for� randomizing� the� user� data� before�
�radio� transmission.� The� data� is� whitened� using� a�
�random� sequence� on� the� TX� side� and� dewhitened� on�
�3.11.4.1�
�Manchester� Data� Encoding�
�the� RX� side� using� the� same� sequence.� Compared� to�
�Manchester� encoding/decoding� is� enabled� by� setting�
�the� MCHSTREN� bit� (PLOADREG<7>)� and� can� be�
�used� in� Packet� mode� only.� The� NRZ� data� is� converted�
�to� Manchester� code� by� coding� ‘� 1� ’� as� ‘� 10� ’� and� ‘� 0� ’� as� ‘� 01� ’.�
�Figure� 3-29� illustrates� Manchester� data� encoding.� NRZ�
�data� is� converted� to� Manchester� by� encoding� 1� bits� as�
�10� chip� sequences,� and� 0� bits� as� 01� chip� sequences.�
�Manchester� encoding� guarantees� DC-balance� and�
�frequent� data� transitions� in� the� encoded� data.� The�
�maximum� Manchester� chip� rate� corresponds� to� the�
�maximum� bit� rate� given� in� the� Transmitter� Electrical�
�specifications� in� Table� 5-6� .�
�Manchester� technique� it� has� the� advantage� of� retaining�
�the� NRZ� data� rate� (that� is,� actual� bit� rate� is� not� halved).�
�The� whitening/dewhitening� process� is� enabled� by�
�setting� the� WHITEN1� bit� (PKTCREG<4>).� A� 9-bit�
�Linear� Feedback� Shift� Register� (LFSR)� is� used� to�
�generate� a� random� sequence.� The� payload� and� 2-byte�
�CRC� checksum� is� then� XORed� with� this� random�
�sequence� as� illustrated� in� Figure� 3-31� .� The� data� is�
�dewhitened� on� the� receiver� side� by� XORing� with� the�
�same� random� sequence.�
�Payload� whitening/dewhitening� is� made� transparent� for�
�the� user,� who� still� provides/retrieves� NRZ� data� to/from�
�the� FIFO.�
�FIGURE� 3-29:�
�FIGURE� 3-30:�
�MANCHESTER� DATA� ENCODING�
�MANCHESTER� ENCODING/DECODING�
�1/BR� 1/� ...Sync�
�BR�
�Payload...�
�RF� chips� @� BR�
�...�
�1�
�1�
�1�
�0�
�1�
�0�
�0�
�1�
�00�
�1�
�0� 1� 10�
�1�
�0�
�...�
�User/NRZ� bits�
�Manchester� OFF�
�...�
�1�
�1�
�1�
�0�
�1�
�0�
�0�
�1�
�00�
�1�
�0�
�1�
�10�
�1�
�0�
�...�
�t�
�User/NRZ� bits�
�Manchester� ON�
�...�
�1�
�1�
�1�
�0�
�1�
�0�
�0�
�10�
�01�
�1�
�...�
�DS70622C-page� 86�
�Preliminary�
�?� 2010–2011� Microchip� Technology� Inc.�
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