参数资料
| 型号: | EVAL-ADV7195EB |
| 厂商: | Analog Devices Inc |
| 文件页数: | 21/36页 |
| 文件大小: | 0K |
| 描述: | BOARD EVAL FOR ADV7195 |
| 标准包装: | 1 |
| 主要目的: | 视频,视频处理 |
| 嵌入式: | 否 |
| 已用 IC / 零件: | ADV7195 |
| 主要属性: | 多格式顺序扫描/HDTV 编码器,3 个 11 位 ADC |
| 次要属性: | 内部测试样式发生器,带颜色控制 |
| 已供物品: | 板 |
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����ADV7195�
�FILTER� GAIN�
�FG� (FG7–FG0)�
�(Address� (SR4–SR0)� =� 10H)�
�Figure� 34� shows� the� various� operations� under� the� control� of� the�
�Filter� Gain� register.�
�The� response� of� the� curve� is� programmed� at� seven� predefined�
�locations.� In� changing� the� values� at� these� locations� the� gamma�
�curve� can� be� modified.� Between� these� points� linear� interpola-�
�tion� is� used� to� generate� intermediate� values.� Considering� the�
�curve� to� have� a� total� length� of� 256� points,� the� seven� locations�
�are� at:� 32,� 64,� 96,� 128,� 160,� 192,� 224.�
�FG7�
�FG6�
�FG5�
�FG4�
�FG3�
�FG2�
�FG1�
�FG0�
�Locations� 0,� 16,� 240,� and� 255� are� fixed� and� cannot� be� changed.�
�FG7� –� FG4�
�FILTER� GAIN� B�
�FG3� –� FG0�
�FILTER� GAIN� A�
�For� the� length� of� 16� to� 240� the� gamma� correction� curve� has� to�
�be� calculated� as� below:�
�y� =� x� γ�
�0000�
�0001�
�0010�
�0011�
�0100�
�0101�
�0110�
�0111�
�1000�
�1001�
�1010�
�1011�
�1100�
�1101�
�1110�
�1111�
�0�
�1�
�2�
�3�
�4�
�5�
�6�
�7�
�–� 8�
�–� 7�
�–� 6�
�–� 5�
�–� 4�
�–� 3�
�–� 2�
�–� 1�
�0000�
�0001�
�0010�
�0011�
�0100�
�0101�
�0110�
�0111�
�1000�
�1001�
�1010�
�1011�
�1100�
�1101�
�1110�
�1111�
�0�
�1�
�2�
�3�
�4�
�5�
�6�
�7�
�–� 8�
�–� 7�
�–� 6�
�–� 5�
�–� 4�
�–� 3�
�–� 2�
�–� 1�
�where�
�y� =� gamma� corrected� output.�
�x� =� linear� input� signal.�
�γ� =� gamma� power� factor.�
�To� program� the� gamma� correction� registers,� the� seven� values�
�for� y� have� to� be� calculated� using� the� following� formula:�
�y� n� =� [� x� (� n� –16)� /(240� –� 16)]� γ� ×� (240–16)� +� 16�
�where�
�x� (n–16)� =� Value� for� x� along� x-axis� at� points:�
�Figure� 34.� Filter� Gain� Register�
�n�
�y� n�
�=� 32,� 64,� 96,� 128,� 160,� 192,� or� 224.�
�=� Value� for� y� along� the� y-axis,� which� has� to� be� written�
�FG� BIT� DESCRIPTION�
�Filter� Gain� A� (FG3–FG0)�
�These� bits� are� used� to� program� the� gain� A� value,� which� varies�
�from� response� –8� to� response� +7� and� are� applied� to� Filter� A.�
�Filter� Gain� B� (FG4–FG7)�
�These� bits� are� used� to� program� the� gain� B� value,� which� varies�
�from� response� –8� to� response� +7,� and� are� applied� to� Filter� B.�
�Refer� to� Sharpness� Filter� Control� and� Adaptive� Filter� Control�
�section� for� more� detail.�
�GAMMA� CORRECTION� REGISTERS� 0–13�
�into� the� gamma� correction� register.�
�Example:�
�y� 32� =� [(16/224)� 0.5� � 2� 24]� +� 16� =� 76� *�
�y� 64� =� [(48/224)� 0.5� � 224]� +� 16� =120� *�
�y� 96� =� [(80/224)� 0.5� � 224]� +� 16� =� 150� *�
�y� 128� =� [(112/224)� 0.5� � 224]� +� 16� =� 174� *�
�*� Rounded� to� the� nearest� integer.�
�The� above� will� result� in� a� gamma� curve� shown� on� the� next�
�page,� assuming� a� ramp� signal� as� an� input.�
�300�
�(GAMMA� CORRECTION� 0–13)�
�(Address� (SR5–SR0)� =� 14H–21H)�
�The� Gamma� Correction� Registers� are� 14� 8-bit-wide� registers.�
�They� are� used� to� program� the� gamma� correction� Curves� A� and� B.�
�250�
�200�
�GAMMA� CORRECTION� BLOCK� OUTPUT�
�TO� A� RAMP� INPUT�
�SIGNAL OUTPUT�
�Generally,� gamma� correction� is� applied� to� compensate� for� the�
�nonlinear� relationship� between� signal� input� and� brightness�
�level� output� (as� perceived� on� the� CRT).� It� can� also� be� applied�
�wherever� nonlinear� processing� is� used.�
�Gamma� correction� uses� the� function:�
�150�
�100�
�0.5�
�Signal� OUT� =� (S� ignal� IN� )� γ�
�where� γ� =� gamma� power� factor.�
�50�
�SIGNAL INPUT�
�Gamma� correction� is� performed� on� the� luma� data� only.�
�0�
�0�
�50�
�100�
�150�
�LOCATION�
�200�
�250�
�The� user� has� the� choice� of� two� different� curves,� Curve� A� or�
�Curve� B.� At� any� one� time� only� one� of� these� curves� can� be� used.�
�REV.� A�
�–21� –�
�Figure� 35.� Signal� Input� (Ramp)� and� Signal� Output� for�
�Gamma� 0.5�
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