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VP536E NTSC/PAL Digital Video Encoder DS4322 - 3.2 August 1997 FEATURES s Converts RGB data (3x8bits) to analog composite video and S-video s Internal video timing generation s RGB or YUV input modes s Progressive scanning (non-interlaced fields) display mode optional s Separate horizontal and vertical sync outputs s 68 pin PLCC package DESCRIPTION The VP536E converts digital RGB data (3x8bits) into analog NTSC/PAL composite video and S-video signals. The outputs are capable of driving doubly terminated 75 ohm loads with standard video levels. The device will also accept YUV data. Progressive scan (non-interlaced fields) video display is available in both NTSC and PAL modes. The output pixel rate is approximately 7 times Fsc (color subcarrier frequency) for NTSC (6.6 times Fsc for PAL) which is approximately 25MHz. Input pixel rate is half this frequency; approximately 12.5MHz. All the necessary synchronization signals are generated internally. Digital horizontal and vertical sync outputs are available for use by the host system. The rise and fall times of sync, burst envelope and video blanking are internally controlled to be within composite video specifications. Two 8-bit digital to analog converters (DACs) are used to convert the digital luminance and chrominance data into analog signals. An inverted composite video signal is generated by summing the complimentary current outputs of each DAC. An internally generated reference voltage provides the biasing for the DACs. APPLICATIONS s s s s s s Multi-media Video Games PC's Graphics Display Adaptors Video Effects Processors CTRLB1 VS CTRLB2 COMPOSITE SYNC VIDEO TIMING GENERATOR HS MATRIX BYPASS BURST GATE R0:7 Y RGB INTERPOLATOR (SIN X/X)-1 PRECOMPENSATION LUMAOUT LUMA DAC COMPOUTB G0:7 TO YUV MATRIX U CHROMA LOW-PASS FILTER INTERPOLATOR BANDPASS MODULATOR FILTER CHROMA DAC CHROMAOUT B0:7 V COLOR SUBCARRIER GENERATOR CLK25I CLK12I CLK25O CLK12O CTRLA1 CTRLA2 CTRLA3 Fig. 1. Functional Block Diagram VP536E NTSC/PAL Video Standards Both NTSC (4-field, 525 lines) and PAL (8-field, 625 lines) video standards are supported by the VP536E. All raster synchronization, color subcarrier and burst characteristics are adapted to the standard selected. However, different input clock frequencies are necessary for each of the two video standards. For the NTSC mode of operation, input clock frequencies of 25.048948MHz. and 12.524474MHz. are required. For the PAL mode of operation, the required input clock frequencies are 29.500000MHz. and 14.750000MHz. The two input clock frequencies in each of the video standards are related by a ratio of 2. The mode of operation is selected through the CTRLB1 and CTRLB2 pins as shown in Table 1. (VS) pulse signals. The HS and VS signals are negative true pulses coincident with the sync pulses in the output video signals. The HS signal has the same duration as a standard horizontal sync pulse but is continuous through the vertical sync interval. Input Pixel Data Format Input pixel data may be in one of two formats; pregamma corrected RGB and YUV. This format is controlled by the state of theCTRLA1, CTRLA2 and CTRLA3 pins as shown in Table 2. The RGB input data coding is straight binary and is in the range of 0-255. In the YUV input mode, Y, U and V data is presented on the R, B and G input data buses, respectively. Y data coding is binary and is in the range of 0-247. U and V coding is in two's compliment binary. U is in the range of 102 to +102 and V is in the range of -107 to +107. Progressive Scan Display Progressive scan (non-interlaced fields) display mode is available for semi-NTSC and semi-PAL video applications. For NTSC, there are 263 lines in each field instead of 262.5 lines per field in a normal NTSC display. Thus, 263 lines of field 2 data are scanned as field 1 resulting in 526 lines per `frame'. For PAL, there are 313 lines in each field instead of 312.5 lines per field in a normal PAL display. Thus, 313 lines of field 2 data are scanned as field 1, resulting in 626 lines per `frame'. Progressive scanning display mode is selected through the CTRLB1 and CTRLB2 pins as shown in Table 1. Table 1: VP536E Modes of Operation CTRLB2 0 0 1 1 CTRLB1 0 1 0 1 Video Standard Dithering In applications where the input RGB/YUV data has been subject to video compression, visual artefacts may occur in the video display depending on the type and quality of video compression employed. The VP536E incorporates dithering techniques on the incoming RGB data and on the internal luminance data in order to minimize any artefacts. Each of these dithering techniques can be enabled or disabled through the CTRLA1 and CTRLA2 pins as shown in Table 2 below. Table 2: Input Pixel Data Format and Dithering Selection CTRLA3 CTRLA2 CTRLA1 Input Pixel Data Format RGB input dither ON, Luma dither OFF RGB input dither ON, Luma dither ON RGB input dither OFF, Luma dither ON RGB input dither OFF, Luma dither OFF YUV input, Luma dither ON YUV input, Luma dither OFF reserved reserved NTSC Progressive Scan NTSC PAL Progressive Scan PAL 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1 NOTE: CTRLB1 & CTRLB2 are internally pulled low, therefore, if left unconnected, NTSC is the default mode of operation. Video Timing The VP536E has an internal sync generator which produces video timing signals appropriate to the mode of operation. All timing signals are derived from the two input clocks. These clocks are input on the CLK25I pin (25.048948MHz:NTSC/29.5MHz:PAL) and the CLK12I pin (12.52444MHz:NTSC/14.75MHz:PAL). The two input clock frequencies for NTSC and PAL are related by a ratio of 2. The lower frequency corresponds to the input pixel data rate. Input pixel data is latched in on the rising edge of the CLK12I clock. The clocks must be derived from a crystal controlled oscillator in order to avoid timing, chroma frequency and modulation errors. The video timing generator produces the internal composite sync, blanking and burst gate as well as externally available horizontal sync (HS) and vertical sync NOTE: CTRLA1 is internally pulled high, while CTRLA2 & CTRLA3 are internally pulled low; therefore if left unconnected, pre-gamma corrected RGB is the default input pixel data format with input RGB and luma dithering enabled. Video Blanking The VP536E automatically performs standard composite video blanking. Lines 1-17, 261-279, 523-525 inclusive, as well as the last half of line 260 and the first half of line 280 are blanked in the NTSC mode. In PAL mode, lines 1-22, 311-335, 624-625 inclusive, as well as the last half of line 623 and the first half of line 23 are blanked. 2 VP536E The host pixel data can be phased relative to the active video timing by counting the CLK12I clock periods from the rising edge of HS. NTSC active video starts 48 CLK12I clock cycles after the rising edge of the horizontal sync pulse output, and PAL active video starts 58 CLK12I clock periods after the rising edge of HS (HS and VS pulse edges coincide with the rising edge of the CLK12I clock). Input pixel data is ignored during the composite blanking periods. external gain setting resistors between the LUMAGAIN, CHROMAGAIN pins and GND. For the correct DAC gains in the NTSC & PAL modes, the LUMAGAIN resistance should be 837ohms. The CHROMAGAIN resistance should be 520ohms for the proper corresponding chroma amplitude (including sinx/x compensation). Color Space Matrix The RGB color space is converted to a YUV color space, using a transformation matrix defined by the NTSC and PAL colorimetry definitions. If the input data format is YUV, this block is bypassed without affecting the overall data latency. Luminance, Chrominance & Composite Video Outputs The Luminance video output (LUMAOUT pin) drives a 37.5 ohm load at 1.0V, sync tip to peak white. It contains only the image's luminance content plus the composite synchronization pulses. The chrominance video output (CHROMAOUT pin) drives a 37.5 ohm load at levels proportional in amplitude to the luma output. This output has a fixed offset current which will produce approximately a 0.5V DC bias across the 37.5 ohm load. Burst is injected with appropriate timing relative to the luma signal. Luma, Chroma and true Composite video signals may be obtained simultaneously through the use of an external inverting video amplifier with the inverted composite video output (COMPOUTB pin). The inverted composite video output has a fixed DC offset. Sync tip is the most positive voltage and is approximately 1.5V with a 37.5 ohm load. The NTSC and PAL output video waveforms of the luma, chroma and inverted composite signals for 100% amplitude, 100% saturated color bars are shown in Figs. 3-8. Interpolator The luminance and chrominance data is separately passed through interpolating filters to produce output sampling rates double that of the incoming pixel rate. This reduces the sinx/x distortion that is inherent in the digital to analog converters and also simplifies the analog reconstruction filter requirements. Sinx/x Distortion Precompensation The luminance data is precompensated for the sinx/x distortion that is inherent in the digital to analog converters. Since the chrominance data is contained within a relatively narrow frequency range, it's sinx/x distortion is compensated for by increasing the gain of the chrominance DAC by a fixed amount. Digital To Analog Converters The VP536E contains two 8-bit digital to analog converters which produce the analog video signals. The DACs use a current steering architecture in which bit currents are routed to one of two outputs; thus each DAC has a true and complimentary output. The use of identical current sources and current steering their outputs means that monotonicity is guaranteed. An on-chip voltage reference of 1.0V (typ.) provides the necessary biasing. However, the VP536E may be used in applications where an external 1V reference is provided, in which case the external reference should be temperature compensated and provide a low impedance output. The full-scale output currents of the DACs is set by external resistors between the LUMAGAIN, CHROMAGAIN and GND pins. An on-chip loop amplifier stabilizes the fullscale output current against temperature and power supply variations. By summing the complimentary current outputs of the two DACs, an inverted composite video signal is obtained. Note that this signal has a DC offset. The analog outputs of the VP536E are capable of directly driving a 37.5 ohm load, such as a doubly terminated 75 ohm co-axial cable. Extendable S-Video Bandwidth The bandwidth of color baseband signals is typically limited in order to avoid modulation problems that develop in composite video due to the interleaving of the chrominance and luminance frequency components. The VP536E can use either traditional bandwidth limited or extended bandwidth baseband signals. For applications where the composite signal is the main source of the video display, it is recommended that bandwidth limiting be used in order to reduce "dot-crawl" effects in the display. For S-Video applications where the luma and chroma signals are separate, enabling the extended bandwidth will result in improved picture definition. The enabling/disabling of this bandwidth extension is controlled through the TCSPK pin as shown below. Table 3: Bandwidth Control TCSPK 0 1 Chroma Bandwidth Extended Bandwidth Limited Bandwidth DAC Gain Adjust The gains of the luma and chroma DACs are independently adjustable. The gains are adjusted using the NOTE: TCSPK is internally pulled LOW, therefore Extended Bandwidth is the default selection. 3 VP536E Master Reset The VP536E can be initialized with the RESET pin. This is an active low signal and must be active for a minimum of 2 CLK12I clock periods in order for the VP536E to be reset. Video Timing Reset The VP536E also features the ability to independently reset the video timing generator without affecting the data path. The TSURST pin controls this function. Taking this pin high resets the video timing generator. If this pin is left open, it is internally pulled low. 48 Periods CLK12I HS Line 1 Line 2 Line 3 Line 4 Line 17 VS Field 1 Line 17 RGB/YUV INPUT DATA Fig. 2a. NTSC Input Timing Diagram 1st pixel 2nd pixel 58Periods CLK12I HS Line 1 Line 2 Line 3 Line 4 Line 23 VS Field 1 Line 23 RGB/YUV INPUT DATA Fig. 2b. PAL Input Timing Diagram 1st pixel 2nd pixel NOTE: 1. Coincident falling edges of HS and VS denote the start of an odd field. 2. VS is low during the first 3 lines in each NTSC field and during the first 21/2 lines in each PAL field. 3. Input pixel data is ignored during composite blanking periods. 4 VP536E Fig. 3. NTSC Luminance Video Output Waveform 100% saturation, 100% amplitude color bars. LUMAGAIN resistor = 837 ohms, VREF=1.0V, 37.5 ohm load. 100 IRE mA 27.29 V 1.023 WHITE LEVEL 8.25 0.309 43 IRE BLANK/BLACK LEVEL SYNC LEVEL 0.00 0.000 Fig. 4. NTSC Chrominance Video Output Waveform 100% saturation, 100% amplitude color bars. CHROMAGAIN resistor = 520 ohms, VREF=1.0V, 37.5 ohm load. mA 27.42 V 1.028 19.20 15.39 11.58 0.720 20 IRE 0.577 20 IRE 0.434 COLOR BURST BLANK LEVEL 3.37 0.126 Fig. 5. NTSC Inverted Composite Video Output Waveform 100% saturation, 100% amplitude color bars. LUMAGAIN resistor = 837 ohms, CHROMAGAIN resistor = 520 ohms, VREF=1.0V, 37.5 ohm load mA mA 42.56 40.69 38.12 34.31 30.50 V V 1.596 1.526 1.430 1.287 1.144 43 IRE 20 IRE 20 IRE 100 IRE 15.27 0.573 31 IRE 8.92 0.335 5 VP536E Fig. 6. PAL Luminance Video Output Waveform 100% saturation, 100% amplitude color bars. LUMAGAIN resistor = 837 ohms, VREF=1.0V, 37.5 ohm load. mA 27.29 V 1.023 WHITE LEVEL 8.25 0.309 BLANK/BLACK LEVEL SYNC LEVEL 0.00 0.000 Fig. 7. PAL Chrominance Video Output Waveform 100% saturation, 100% amplitude color bars. CHROMAGAIN resistor = 520 ohms, VREF=1.0V, 37.5 ohm load. mA 27.42 V 1.028 19.53 15.39 11.26 0.732 0.577 0.422 COLOR BURST BLANK LEVEL 3.37 0.126 Fig. 8. PAL Inverted Composite Video Output Waveform 100% saturation, 100% amplitude color bars. LUMAGAIN resistor = 837 ohms, CHROMAGAIN resistor = 520 ohms, VREF=1.0V, 37.5 ohm load mA mA 42.56 40.69 38.44 34.31 30.17 V V 1.596 1.526 1.442 1.287 1.131 15.27 0.573 8.92 0.335 6 VP536E Pin Descriptions Table 4: Pin Descriptions Pin Name B0-B7 G0-G7 R0-R6, R7 Pin No. 2-9 17-24 62-68, 1 Description 8 Bit Blue data inputs. B0 is the least significant bit, corresponding to Pin 2. These pins are internally pulled low. 8 Bit Green data inputs. G0 is the least significant bit. These pins are internally pulled low. 8 Bit Red data inputs. R7 is the most significant bit corresponding to Pin 1. These pins are internally pulled low. 2X pixel rate clock input. The VP536E requires a clock whose frequency is twice the input pixel data rate; i.e., 25.0489484MHz. for the NTSC mode of operation; 29.500000MHz. for the PAL mode of operation.This clock must be derived from a crystal controlled oscillator in order to avoid chroma frequency, modulation and timing errors. Pixel rate clock input. The frequency of this clock must be exactly half that of the CLK25I clock. The rising edges of these two clocks must be synchronous. 2X pixel rate clock output. The CLK25I clock is output on this pin. Note that this output clock signal is inverted with respect to the CLK25I clock. Pixel rate clock output. The CLK12I clock is output on this pin. Horizontal sync pulse output. This is an active low signal output, i.e. the presence of a sync pulse is denoted by the signal being low. Vertical sync pulse output. This is an active low signal output. VP536E master reset. This is an active low input signal and must be asserted for a minimum of 2 CLK12I clock periods in order to reset the VP536E. Input data format and dithering control. Control codes on these three input pins determine the format of the input data as described in Input Pixel Data Format on Page 2. CTRLA1 is internally pulled high, while CTRLA2 and CTRLA3 are internally pulled low; therefore if left open, the default input data format is pregamma corrected RGB with dithering as described on Page 2. Video standard control. Control codes on these two input pins determine the video display mode as described in Table 1 on Page 2. These pins are internally pulled low, therefore if left open, the default video display mode is NTSC. Enable/Disable extended video bandwidth. Taking this pin high limits the bandwidth of the video signal as described in Extendable S-Video Bandwidth on Page 3. This pin is internally pulled low, therefore if left open, extended bandwidth is enabled. Synchronous reset of video timing. An active high pulse on this pin resets the video timing generator without affecting the data path. On the rising edge of CLK12I following TSURST going low, Field 1, line 1 is initiated. This pin is internally pulled low. Voltage reference output. This output is nominally 1.0V and should be decoupled with a 1.0F capacitor to GND. Luma DAC compensation. A 0.1F ceramic capacitor must be connected between this pin and it's neighboring VAA pin (pin 31). Chroma DAC compensation. A 0.1F ceramic capacitor must be connected between this pin and it's neighboring VAA pin (pin 37). Luminance, inverted composite and chrominance video signal outputs. These outputs are high impedance current source outputs. A DC path to GND must exist from each of these pins. Luminance full scale current control. A resistor connected between this pin and GND sets the magnitude of the luminance video output current. An internal loop amplifier controls a reference current flowing through this resistor so that the voltage across it is equal to the Vref voltage. This reference current has a weighting equal to 16 LSB's. Note that the IRE relationships shown in Fig. 3 are maintained, regardless of the output full scale current. CLK25I 57 CLK12I CLK25O CLK12O HS VS RESET CTRLA1 CTRLA2 CTRLA3 CTRLB1 CTRLB2 60 61 51 14 13 16 59 58 54 52 53 TCSPK 49 TSURST 50 VREF LUMACOMP CHROMACOMP LUMAOUT COMPOUTB CHROMAOUT 28 30 38 32 34 36 LUMAGAIN 29 7 VP536E Table 4: Pin Descriptions (Continued) Pin Name Pin No. Description Chrominance full scale current control. As with the LUMAGAIN pin, a resistor between this pin and GND controls the magnitude of the chrominance video signal. An internal loop amplifier adjusts a reference current flowing through this resistor so that the voltage across it is equal to the Vref voltage. This reference current has a weighting equal to 16 LSB's. These pins must be held low. Test mode control. These two pins are used to configure the VP536E into various test modes. They should be held low during normal operation. Power. All VAA pins must be connected. CHROMAGAIN 39 TEST0-TEST7 CTRLC1 CTRLC2 VAA 41-48 15 12 10, 25, 31, 37, 40, 55 11, 26, 56 27, 33, 35 GND Ground. All GND pins must be connected. RECOMMENDED OPERATING CONDITIONS Parameter Power supply voltage Input clock frequency CLK25I (NTSC) CLK12I (NTSC) CLK25I (PAL) CLK12I (PAL) CLK25I & CLK12I rising edges must be synchronous Symbol VAA Min. 4.75 Typ. 5.00 25.048948 12.524474 29.500000 14.750000 Max. 5.25 Units V MHz. MHz. MHz. MHz. Input clock frequency accuracy Analog video output load Gain resistors Lumagain resistor (NTSC) Chromagain resistor (NTSC) Lumagain resistor (PAL) Chromagain resistor (PAL) Ambient operating temperature 0 37.5 837 520 837 520 25 ppm 70 oC ABSOLUTE MAXIMUM RATINGS (Referenced to GND) Parameter Power supply Voltage on any non-power pin Analog video output short circuit duration Ambient operating temperature Storage temperature 0 -40 Symbol VAA Min. -0.3 -0.3 Indefinite 70 125 o o Typ. Max. 7 VAA + 0.3 Units V V C C NOTE: Stresses exceeding those listed under Absolute Maximum Ratings may induce failure. Exposure to absolute maximum ratings for extended periods may reduce reliability. Functionality at or above these conditions is not implied. 8 VP536E ELECTRICAL CHARACTERISTICS Test conditions (unless otherwise stated): As specified in Recommended Operating Conditions DC Characteristics (see note on Page 11) Parameter Resolution (each DAC) Accuracy (each DAC) Integral linearity error Differential linearity error Gray scale error Monotonicity Analog video output compliance Digital Inputs Input high voltage Input low voltage Digital Outputs Output high voltage (IOH = -10.0 mA) Output low voltage (IOL = 10.0 mA) Luminance video output current White level relative to black/blank level (NTSC) Black/Blank level relative to sync level (NTSC) White level relative to black/blank level (PAL) Black/blank level relative to sync level (PAL) Chrominance video output current Blank level (NTSC) Peak chroma level relative to blank level (NTSC) (corresponding to 100% saturated red) Peak burst level relative to blank level (NTSC) Blank level (PAL) Peak chroma level relative to blank level (PAL) (corresponding to 100% saturated red) Peak burst level relative to blank level (PAL) Internal reference voltage Internal reference voltage output impedance VREF INL DNL Guaranteed VAVOC VIH VIL VOH VOL -0.3 3.0 0.8 VAA - 1 0.4 18.11 7.67 18.11 7.67 19.04 8.25 19.04 8.25 19.97 8.83. 19.97 8.83 1.6 V V V V V mA mA mA mA Symbol Min. 8 +/- 1.5 +/- 1 +/- 5 Typ. Max. Units Bits LSB LSB % gray scale 14.62 +/- 10.95 +/- 3.46 14.62 +/- 10.95 +/- 3.77 0.95 15.39 +/- 12.03 +/- 3.81 15.39 +/- 12.03 +/- 4.14 1.00 25 16.16 +/- 13.11 +/- 4.16 16.16 +/- 13.11 +/- 4.51 1.05 mA mA mA mA mA mA V K 9 VP536E AC Characteristics (see note on Page 11) Parameter CLK12I clock delay with respect to CLK25I clock (tested with 50% duty cycle CLK12I and CLK25I clocks) Symbol tdCLK tsuDATA thDATA tdSYNC twHS-NTSC twHS-PAL twVS-NTSC twVS-PAL Min. 0 8 5 0 Typ. Max. 18 Units ns ns ns Data set-up time (wrt CLK12I clock) Data hold time (wrt CLK12I clock) HS/VS output delay wrt CLK12I clock HS low pulse width (NTSC) HS low pulse width (PAL) VS low pulse width(NTSC) VS low pulse width (PAL) Input clock pulse width high time Input clock pulse width low time Analog video output delay (wrt CLK25I clock) Analog video output rise/fall time Analog video output settling time (50% to +/- 1 LSB) Signal related harmonics of DAC outputs for 1MHz. direct digitally synthesized sine wave Pipeline delay (data in to analog video out) VAA supply current Power supply rejection (chromacomp, lumacomp = 0.1uF, f = 1 KHz.) 20 59 69 2388 2360 ns CLK12I cycles CLK12I cycles CLK12I cycles CLK12I cycles 16 16 tdAVO trfAVO tsAVO 10 8 12 tbd 20.5 IAA 200 40 ns ns ns ns ns dB CLK12I cycles mA dB Timing Waveforms CLK25I tdCLK CLK12I tsuDATA thDATA RGB DATA tdSYNC HS/VS tdAVO twHS twVS tsAVO LUMAOUT, CHROMAOUT, COMPOUTB trfAVO Fig. 9. Input/Output Timing Diagram 10 VP536E Video Characteristics (see note below) Parameter Luminance bandwidth (Extended Bw mode) Luminance bandwidth (Reduced Bw mode) Chrominance bandwidth (Extended Bw mode) Chrominance bandwidth (Reduced Bw mode) Burst frequency (NTSC) Burst frequency (PAL) Burst cycles (NTSC) Burst cycles (PAL) Burst envelope rise/fall time Analog video sync rise/fall time Analog video blank rise/fall time Differential gain Differential phase Signal to Noise Ratio (white field) Chroma AM signal to noise ratio (100% red field) Chroma PM signal to noise ratio (100% red field) Hue accuracy Color saturation accuracy Residual subcarrier Luminance/chrominance delay -60 20 Symbol Min. Typ. 4.0 2.5 1.8 1.2 3.579545 4.433619 10 10 1.5 90 160 1.5 1.0 60 58 56 2.5 2.5 Max. Units MHz. MHz. MHz. MHz. MHz. MHz. Fsc cycles Fsc cycles Fsc cycles ns ns % pk-pk o pk-pk dB dB dB degrees % dB ns NOTE: The DC, AC and Video characteristics listed above are based on design targets and/or actual measurements on a limited number of devices. All parametric information is subject to review following further characterization. 11 VP536E Package Details and Pin-Out 68 Pin PLCC Package 0.985" - 0.995" (25.02mm - 25.27mm) SQ. 0.944" - 0.964" (23.98mm - 24.48mm) SQ. Pin No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 Pin Name R7 B0 B1 B2 B3 B4 B5 B6 B7 VAA GND CTRLC2 VS HS CTRLC1 RESET G0 G1 G2 G3 G4 G5 G6 G7 VAA GND GND VREF LUMAGAIN LUMACOMP VAA LUMAOUT GND COMPOUTB Pin No. 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 Pin Name GND CHROMAOUT VAA CHROMACOMP CHROMAGAIN VAA TEST0 TEST1 TEST2 TEST3 TEST4 TEST5 TEST6 TEST7 TCSPK TSURST CLK12O CTRLB1 CTRLB2 CTRLA3 VAA GND CLK25I CTRLA2 CTRLA1 CLK12I CLK25O R0 R1 R2 R3 R4 R5 R6 Pin No. 26 Pin No. 27 Pin No. 10 Pin No. 9 Pin No. 1 Pin No. 43 Pin No. 44 Pin No. 61 Pin No. 60 0.165" - 0.185" (4.19mm - 4.70mm) 0.050" NOM. (1.27mm NOM.) 0.800" NOM. (20.32mm NOM.) Ordering Information VP536E/??/???? HEADQUARTERS OPERATIONS MITEL SEMICONDUCTOR Cheney Manor, Swindon, Wiltshire SN2 2QW, United Kingdom. Tel: (01793) 518000 Fax: (01793) 518411 MITEL SEMICONDUCTOR P.O. Box 660017 1500 Green Hills Road, Scotts Valley, California 95067-0017, United States of America. Tel: (408) 438 2900 Fax: (408) 438 5576 Internet: http://www.gpsemi.com CUSTOMER SERVICE CENTRES s s s s s s s s s s FRANCE & BENELUX Les Ulis Cedex Tel: (1) 69 18 90 00 Fax: (1) 64 46 06 07 GERMANY Munich Tel: (089) 4195 08-0 Fax: (089) 4195 08-55 ITALY Milan Tel: (02) 6607151 Fax: (02) 66040993 JAPAN Tokyo Tel: (03) 5276-5501 Fax: (03) 5276-5510 KOREA Seoul Tel: (2) 5668141 Fax: (2) 5697933 NORTH AMERICA Scotts Valley, USA Tel (408) 438 2900 Fax: (408) 438 7023. SOUTH EAST ASIA Singapore Tel: (65) 3827708 Fax: (65) 3828872 SWEDEN Stockholm Tel: 46 8 702 97 70 Fax: 46 8 640 47 36 TAIWAN, ROC Taipei Tel: 886 2 5461260. Fax: 886 2 7190260 UK, EIRE, DENMARK, FINLAND & NORWAY Swindon Tel: (01793) 518527/518566 Fax: (01793) 518582 These are supported by Agents and Distributors in major countries worldwide (c) Mitel Corporation 1998 Publication No. DS4322 Issue No.3.2 Aug 97 TECHNICAL DOCUMENTATION - NOT FOR RESALE. PRINTED IN THE UNITED KINGDOM This publication is issued to provide information only which (unless agreed by the Company in writing) may not be used, applied or reproduced for any purpose nor form part of any order or contract nor to be regarded as a representation relating to the products or services concerned. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. The Company reserves the right to alter without prior notice the specification, design or price of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user's responsibility to fully determine the performance and suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. These products are not suitable for use in any medical products whose failure to perform may result in significant injury or death to the user. All products and materials are sold and services provided subject to the Company's conditions of sale, which are available on request. All brand names and product names used in this publication are trademarks, registered trademarks or trade names of their resplective owners. For more information about all Zarlink products visit our Web Site at www.zarlink.com Information relating to products and services furnished herein by Zarlink Semiconductor Inc. trading as Zarlink Semiconductor or its subsidiaries (collectively "Zarlink") is believed to be reliable. However, Zarlink assumes no liability for errors that may appear in this publication, or for liability otherwise arising from the application or use of any such information, product or service or for any infringement of patents or other intellectual property rights owned by third parties which may result from such application or use. Neither the supply of such information or purchase of product or service conveys any license, either express or implied, under patents or other intellectual property rights owned by Zarlink or licensed from third parties by Zarlink, whatsoever. Purchasers of products are also hereby notified that the use of product in certain ways or in combination with Zarlink, or non-Zarlink furnished goods or services may infringe patents or other intellectual property rights owned by Zarlink. This publication is issued to provide information only and (unless agreed by Zarlink in writing) may not be used, applied or reproduced for any purpose nor form part of any order or contract nor to be regarded as a representation relating to the products or services concerned. The products, their specifications, services and other information appearing in this publication are subject to change by Zarlink without notice. No warranty or guarantee express or implied is made regarding the capability, performance or suitability of any product or service. Information concerning possible methods of use is provided as a guide only and does not constitute any guarantee that such methods of use will be satisfactory in a specific piece of equipment. It is the user's responsibility to fully determine the performance and suitability of any equipment using such information and to ensure that any publication or data used is up to date and has not been superseded. Manufacturing does not necessarily include testing of all functions or parameters. These products are not suitable for use in any medical products whose failure to perform may result in significant injury or death to the user. All products and materials are sold and services provided subject to Zarlink's conditions of sale which are available on request. Purchase of Zarlink's I2C components conveys a licence under the Philips I2C Patent rights to use these components in an I2C System, provided that the system conforms to the I2C Standard Specification as defined by Philips. Zarlink and the Zarlink Semiconductor logo are trademarks of Zarlink Semiconductor Inc. Copyright 2002, Zarlink Semiconductor Inc. All Rights Reserved. TECHNICAL DOCUMENTATION - NOT FOR RESALE |
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