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�Dual� RF� LDMOS� Bias� Controller� with�
�Nonvolatile� Memory�
�quantities.� But� to� avoid� the� possibility� of� mathematical�
�overflow,� the� magnitude� of� the� values� should� be� limited�
�to� 12� bits� (-4096� to� +4095,� which� allows� full� movement�
�over� the� range� of� the� 12-bit� DAC).�
�Temperature/APC� LUT� Configuration� Registers�
�The� LUT� Configuration� register� (see� Table� 5)� specifies�
�the� location� and� the� size� of� the� temperature� and� auto-�
�matic� power� control� (APC)� LUTs.� The� EEPROM� can� be�
�configured� to� have� a� total� of� four� LUTs� (one� tempera-�
�ture� LUT� for� each� temperature-sensor� channel� and� one�
�APC� LUT� for� each� DAC� channel).� These� registers� can�
�only� be� programmed� when� the� device� is� in� LUT� stream-�
�ing� mode� and� are� set� while� data� is� being� streamed� into�
�the� LUT.� The� data� contained� in� the� LUT� Configuration�
�registers� is� stored� in� the� EEPROM.�
�When� V� GATE_� calculations� are� made� using� temperature�
�and/or� APC� LUT� values,� the� MAX11008� uses� a� LUT�
�pointer� to� retrieve� the� correct� values� for� the� calculation.�
�The� LUT� pointer� value� is� derived� from� the� most� recent�
�12-bit� ADC� measurement� or� directly� transferred� from�
�the� APC� Parameter� register� (see� Table� 16).� The� source�
�of� the� LUT� pointer� value� depends� on� the� settings� of� the�
�Software� Configuration� register� (see� Table� 13).� PSIZE�
�determines� the� size� of� the� LUT� pointer� (see� Table� 5a).�
�TSIZE� specifies� the� size� of� the� table� (see� Table� 5c).� It� is�
�permissible� to� use� an� LUT� pointer� that� is� larger� than� the�
�table� indexed.� An� 8-bit� pointer� functions� properly� with� a�
�LUT� of� 32� data� locations.� The� LUT� pointer� values� that�
�extend� beyond� the� table� are� limited� to� the� upper� (or�
�lower)� bound� of� the� table.� This� technique� increases� the�
�effective� table� resolution� when� the� dynamic� range� of�
�ADC� samples� is� limited.�
�The� POFF� bits� set� the� offset� value� that� is� added� to� the�
�resulting� LUT� pointer� value.� POFF� is� a� signed� 6-bit� value�
�that� is� used� to� apply� both� positive� and� negative� offset�
�values� to� the� LUT� pointer.� The� range� of� acceptable� off-�
�set� values� depends� on� PSIZE� (see� Table� 5a).� POFF� is�
�typically� used� for� temperature� LUTs� that� have� LUT� data�
�for� 0°C� measurements� located� at� the� center� of� the� LUT.�
�For� example,� if� a� temperature� LUT� has� 64� data� locations�
�(locations� 0� through� 63),� the� data� for� 0°C� is� located� at�
�the� center� of� the� LUT� (location� 31).� If� a� temperature�
�measurement� is� made� at� 0°C,� the� resulting� ADC� conver-�
�sion� is� 0,� which� instructs� the� LUT� pointer� to� retrieve� data�
�from� the� first� location� (location� 0)� in� the� LUT.� To� retrieve�
�the� correct� data� for� 0°C� (location� 31),� a� pointer� offset� of�
�31� needs� to� be� added� to� the� LUT� pointer.�
�To� increase� the� accuracy� of� V� GATE_� calculations,� the�
�MAX11008� can� linearly� interpolate� intermediate� temper-�
�ature� and� APC� compensation� values� from� the� two� clos-�
�est� LUT� data� locations.� To� accomplish� this,� fractional�
�bits� are� added� to� the� LUT� pointer� by� setting� the� INT� bits�
�(see� Table� 5b).� When� INT� =� 00� the� LUT� pointer� has� no�
�fractional� bits� and� no� interpolation� is� performed.� When�
�INT� =� 00,� every� LUT� pointer� corresponds� directly� to� a�
�table� entry.� If� INT� =� 01,� the� LUT� pointer� has� 1� fractional�
�bit,� which� represents� a� fractional� 1/2.� This� represents�
�an� LUT� pointer� that� falls� midway� between� two� table�
�entries,� and� the� MAX11008� performs� a� linear� interpola-�
�tion� between� those� two� entries.� Similarly,� INT� =� 10� pro-�
�vides� 2� fractional� bits� (1/4� resolution� or� 4:1�
�interpolation),� and� INT� =� 11� provides� 3� fractional� bits�
�(1/8� resolution� or� 8:1� interpolation).� See� the� Calculating�
�an� LUT� Pointer� from� an� ADC� Sample/APC� Parameter�
�section� for� a� detailed� description� and� examples� on� cal-�
�culating� LUT� pointer� values.�
�The� SOT� bits� set� the� starting� addresses� of� each� corre-�
�sponding� LUT� in� the� EEPROM� (see� Table� 5d).� Each�
�table� starts� at� one� of� six� possible� locations� within� the�
�EEPROM� memory� space.� It� is� also� possible� to� make�
�several� LUT� tables� occupy� the� same� memory� space�
�within� the� EEPROM� by� simply� setting� identical� SOT� val-�
�ues.� This� is� useful� when� temperature� or� APC� data� is�
�common� to� both� channels.� This� allows� a� single� shared�
�table� of� double� the� resolution� to� be� implemented�
�instead� of� two� separate� identical� tables.�
�Tables� 5e� and� 5f� contain� examples� on� how� to� configure�
�the� LUTs� in� EEPROM� using� the� TSIZE,� SOT,� and�
�PSIZE� bits.�
�Calculating� an� LUT� Pointer� from� an� ADC�
�Sample/APC� Parameter�
�Calculate� the� LUT� pointer� value� using� the� following�
�steps:�
�1)� The� 12-bit� ADC� value� is� first� shifted� to� the� right� by�
�the� number� of� bits� as� determined� by� the� following�
�equation:�
�12-bit� ADC� value� right� shift� =� 7� -� PSIZE� -� INT�
�where� PSIZE� and� INT� are� the� decimal� values� of�
�PSIZE� and� INT� in� the� LUT� Configuration� register.� The�
�LUT� pointer� is� interpreted� as� a� fixed-point� fractional�
�number� where� PSIZE� specifies� the� number� of� inte-�
�ger� bits� and� INT� specifies� the� number� of� fractional�
�bits.�
�2)� The� pointer� offset� value� is� left-shifted� in� the� following�
�manner:�
�If� PSIZE� =� 00� or� 01,� no� shifting� is� performed.�
�If� PSIZE� =� 10,� POFF� is� shifted� to� the� left� by� 1� bit.�
�If� PSIZE� =� 11,� POFF� is� shifted� to� the� left� by� 2� bits.�
�POFF� is� interpreted� as� a� signed� number.�
�3)� The� resulting� POFF� value� is� added� to� the� LUT� point-�
�er� value.�
�______________________________________________________________________________________�
�41�
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