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VPX3226E Datasheet(PDF) 19 Page - Micronas |
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VPX3226E Datasheet(HTML) 19 Page - Micronas |
19 / 92 page ADVANCE INFORMATION VPX 322xE MICRONAS INTERMETALL 19 2.7.1.2. Embedded Reference Headers/ITU-R656 The VPX supports an output format which is designed to be compliant with the ITU-R656 recommendation. It is activated by setting bit[1:0] of FP-RAM 0x150 to 01. The 16-bit video data must be multiplexed to 8 bit at the double clock frequency (27 MHz) via FP-RAM 0x154, bit[9] set to 1 (see also Section 2.7.3.: Output Multiplex- er). In this mode, video samples are in the following order: Cb, Y, Cr, Y, ... The data words 0 and 255 are protected since they are used for identification of reference head- ers. This is assured by limitation of the video data. Tim- ing reference codes are inserted into the data stream at the beginning and the end of each video line in the fol- lowing way: A ‘Start of active video’-Header (SAV) is in- serted before the first active video sample. The ‘end of active video’-code (EAV) is inserted after the last active video sample. They both contain information about the field type and field blanking. The data words occurring during the horizontal blanking interval between EAV and SAV are filled with 0x10 for luminance and 0x80 for chro- minance information. Table 2–3 shows the format of the SAV and EAV header. Fig. 2–19 and 2–20 show stan- dard ITU-R656 output waveforms. Note that the following changes and extensions to the ITU-R656 standard have been included to support hori- zontal and vertical scaling, transmission of VBI-data, etc.: – Both the length and the number of active video lines varies with the selected window parameters. For com- pliance with the ITU-R656 recommendation, a size of 720 samples per line must be selected for each win- dow. To enable a constant line length even in the case of different scaling values for the video windows, the VPX provides a programmable ‘active video’ signal (see section 2.9.4.). – During blanked lines, the VACT signal is suppressed. VBI-lines can be marked as blanked or active, thus al- lowing the choice of enabled or suppressed VACT dur- ing the VBI-window. The vertical field blanking flag (V) in the SAV/EAV header is set to zero in any line with enabled VACT signal (valid VBI or video lines). – During blanked lines SAV/EAV headers can be sup- pressed in pairs with FP-RAM 0x150, bit[9]. To assure vertical sync detection, some SAV/EAV headers are inserted during field blanking. – The flags F,V and H encoded in the SAV/EAV headers change on SAV. With FP-RAM 0x150, bit[10] set to 1 they change on EAV. The programmed windows how- ever are delayed by one line. Header suppression is always applied for SAV/EAV pairs. – For data within the VBI-window (e.g. sliced or raw tele- text data), the user can select between limitation or re- duction to 7-bit resolution with an additional LSB as- suring odd parity (0 and 255 never occur). This option can be selected via FP-RAM 0x150 [range]. – The task bit can be used as a qualifier for VBI data. It is set to zero during the programmed VBI window if bit[11] in 0x150 is set. – Ancillary data blocks may be longer than 255 bytes (for raw data) and are transmitted without checksum. The secondary data ID is used as high byte of the data count (DC1; see Table 2–4). – Ancillary data packets must not follow immediately af- ter EAV or SAV. – The total number of clock cycles per line, as well as valid cycles between EAV and SAV may vary. Table 2–3: Coding of the SAV/EAV-header Bit No. Word MSB LSB 7 6 5 4 3 2 1 0 First 1 1 1 1 1 1 1 1 Second 0 0 0 0 0 0 0 0 Third 0 0 0 0 0 0 0 0 Fourth T F V H P3 P2 P1 P0 T= 0 during VBI data (if enabled), else T = 1 F = 0 during field 1, F = 1 during field 2 V = 0 during active lines V = 1 during vertical field blanking H = 0 in SAV, H = 1 in EAV The bits P0, P1, P2, and P3 are protection bits. Their states are dependent on the states of F, V, and H. They can be calculated using the following equations: P3 = H xor V xor T P2 = H xor F xor T P1 = V xor F xor T P0 = H xor V xor F The VPX also supports the transmission of VBI-data as vertical ancillary data during blanked lines in the interval starting with the end of the SAV and terminating with the beginning of EAV. In this case, an additional header is in- serted directly before the valid active data; thus, the position of SAV and EAV depends on the settings for the programmable VACT signal (see Fig. 2–21). These pa- rameters will be checked and corrected if necessary to assure an appropriate size of VACT for both data and an- cillary header. |
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