CXD1914Q Digital Video Encoder For the availability of this product, please contact the sales office. Description The CXD1914Q is a digital video encoder designed for DVDs, set top boxes, digital VCRs and other digital video equipment. This device accepts ITU-R601 compatible Y, Cb and Cr data, and the data are encoded to composite video and separate Y/C video (S-video) signals and converted to RGB/YUV signals. Features • NTSC and PAL encoding modes • Composite video and separate Y/C video (S-video) signal output • R, G, B/Y, U and V (BetaCam/SMPTE level) signal output • 8/16-bit pixel data input modes • 13.5 Mpps pixel rate • 10-bit 6-channel DAC • Supports I2C bus (400 kHz) and Sony SIO • Closed Caption (Line 21, Line 284) encoding • Macrovision Pay-Per-View copy protection system : NTSC Rev. 7.0, PAL Rev. 6.1 (Note 1) • VBID encoding • WSS encoding • Supports non-interlace mode • Monolithic CMOS single 5.0 V power supply • 100-pin plastic QFP 100 pin QFP (Plastic) Absolute Maximum Ratings (Ta=25 °C) • Supply voltage VDD –0.3 to +7.0 • Input voltage VI –0.3 to +7.0 • Output voltage VO –0.3 to +7.0 • Operating temperature Topr –20 to +75 • Storage temperature Tstg –40 to +125 (VSS=0 V) V V V °C °C Recommended Operating Conditions • Supply voltage VDD 4.75 to 5.25 • Input voltage VIN VSS to VDD • Operating temperature Topr 0 to +70 V V °C I/O Pin Capacitance • Input pin • Output pin pF pF CI CO 11 (Max.) 11 (Max.) Note) Test conditions : VDD=VI=0 V, fM=1 MHz (Note 1) This device is protected by U.S. patent numbers 4631603, 4577216 and 4819098 and other intellectual property rights. Use of the Macrovision anticopy process in the device is licensed by Macrovision for non-commercial home use only. Reverse engineering or disassembly is prohibited. Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits. —1— E96Z29-TE —2— SO SI/SDA SCK/SCL XCS/SA XIICEN XVRST VSYNC HSYNC FID CSYNC XRST PD8-15 PD0-7 SYSCLK PDCLK I2C-Bus and SIO Controller LPF LPF Delay CSYNC VBID & WSS Gen. MACRO VISION Signal Gen. Closed Caption Encoder (for NTSC) Sub Carrier Gen. BURST FLAG Y Dempx, Level Translator U and interpolator 4:2:2 to V 4:4:4 Internal CLK SYNC Gen. and Timing Controller 1/2 Modulator YUV/RGB translator SYNC Slope Gen. CROMA Interpolator Interpolator JTAG 10bit DAC 10bit DAC 10bit DAC 10bit DAC 10bit DAC 10bit DAC XTEST1-5 TRST TCK TMS TDI TDO VB VREF IREF VG C-OUT Y-OUT COMP-O B/V-OUT G/Y-OUT R/U-OUT CXD1914Q Block Diagram CXD1914Q Pin Description Pin No. Symbol I/O 1 F1 I 2 3 4 5 6 TVSYNC OSDSW ROSD GOSD BOSD I I I I I 7 XVRST I 8 SYSCLK I 9 VSS1 — 10 XRST I 11 PDCLK O 12 13 VDD1 NC — — 14 FID O 15 16 17 18 VSYNC HSYNC CSYNC VSS2 O O O — 19 PD0 Description Field ID input. This signal indicates the field ID when resetting the vertical sync. “H” indicates 1st field. “L” indicates 2nd field. Test pin. Set “L”. Test pin. Set “L”. Test pin. Set “L”. Test pin. Set “L”. Test pin. Set “L”. Vertical sync reset input in active low. This pin is pulled up. This is used for synchronizing the phases of the external and internal vertical sync signals. When XVRST= “L”, the internal digital sync generator is reset according to the F1 status. System clock input. To generate the correct subcarrier frequency, precise 27 MHz is required. Digital ground. System reset input in active low. Set “L” for 40 clocks (SYSCLK) or more during power-on reset. Pixel data clock signal output for 13.5 MHz. A 13.5 MHz signal frequency divided from the system clock (SYSCLK) is output and used as the clock signal when 16-bit pixel data is input. Digital power supply. Not connected inside the IC. Field ID output. When control register bit “FIDS” = “1”, “L” indicates 1st field and “H” indicates 2nd field. When control register bit “FIDS” = “0”, “H” indicates 1st field and “L” indicates 2nd field. Vertical sync signal output. Horizontal sync signal output. Composite SYNC output when using RGB output. Digital ground. I 20 PD1 I 21 PD2 I 22 PD3 I 23 VDD2 — 8-bit pixel data inputs, or lower 8-bit pixel data inputs when 16-bit pixel data is input. [PD0 to 7] When control register bit “PIF MODE” = “0”, these are multiplexed Y, Cb, and Cr signal inputs. When control register bit “PIF MODE” = “1”, these are Y signal inputs. Digital power supply. —3— CXD1914Q Pin No. 24 Symbol PD4 I/O Description I 8-bit pixel data inputs, or lower 8-bit pixel data inputs when 16-bit pixel data is input. [PD0 to 7] When control register bit “PIF MODE” = “0”, these are multiplexed Y, Cb, and Cr signal inputs. When control register bit “PIF MODE" =“1”, these are Y signal inputs. 25 PD5 I 26 PD6 I 27 PD7 I 28 29 30 31 32 NC NC NC NC NC — — — — — Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. 33 PD8 / TD0 I/O 34 PD9 / TD1 I/O 35 PD10 / TD2 I/O 36 PD11 / TD3 I/O Upper 8-bit pixel data inputs/test data bus when 16-bit pixel data is input. [PD8 to 15] When control register bit “PIF MODE” = “0”, these inputs are not used. When control register bit “PIF MODE” = “1”, these are multiplexed Cb and Cr signal inputs. In the test mode, these are used for the internal circuit test data bus. The test data bus is available only for the device vendor. 37 VSS3 — Digital ground. 38 PD12 / TD4 I/O 39 PD13 / TD5 I/O 40 PD14 / TD6 I/O 41 PD15 / TD7 I/O Upper 8-bit pixel data inputs/test data bus when 16-bit pixel data is input. [PD8 to 15] When control register bit “PIF MODE” = “0”, these inputs are not used. When control register bit “PIF MODE” = “1”, these are multiplexed Cb and Cr signal inputs. In the test mode, these are used for the internal circuit test data bus. The test data bus is available only for the device vendor. 42 VDD3 — 43 XIICEN I 44 XCS/SA I 45 SCK/SCL I 46 VSS4 — Digital power supply. Serial interface mode select input. This pin is pulled up. When XIICEN = “L”, Pins 44, 45, 47 and 48 are I2C bus mode. When XIICEN = “H”, Pins 44, 45, 47 and 48 are Sony SIO mode. This pin’s function is selected by XIICEN (Pin 43). This pin is pulled up. When XIICEN = “H”, this pin is Sony SIO mode ; XCS chip select input. When XIICEN = “L”, this pin is I2C bus mode ; SA slave address select input which selects the I2C bus slave address. This pin’s function is selected by XIICEN (Pin 43). When XIICEN = “H”, this pin is Sony SIO mode ; SCK serial clock input. When XIICEN = “L”, this pin is I2C bus mode ; SCL input. Digital ground. —4— CXD1914Q Pin No. Symbol I/O 47 SI/SDA I/O 48 SO O 49 50 51 52 53 NC NC NC NC NC — — — — — 54 IREF I 55 VREF I 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 CP-OUT AVDD1 C-OUT AVSS1 NC VB VG NC Y-OUT AVDD2 B-OUT AVSS2 NC NC NC NC G-OUT AVDD3 R-OUT AVSS3 NC NC NC NC NC VDD4 O — O — — O O — O — O — — — — — O — O — — — — — — — Description This pin’s function is selected by XIICEN (Pin 43). When XIICEN = “H”, this pin is Sony SIO mode ; SI serial data input. When XIICEN = “L”, this pin is I2C bus mode ; SDA input/output. This pin’s function is selected by XIICEN (Pin 43). When XIICEN = “H”, this pin is Sony SIO mode ; SO serial out output. When XIICEN = “L”, this pin is not used and output is high impedance. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. DAC reference current input. Connect resistance “16R” which is 16 times output resistance “R”. DAC reference voltage input. Sets the DAC output full-scale width. 10-bit DAC output. This pin outputs the composite signal. Analog power supply. 10-bit DAC output. This pin outputs the chroma (C) signal. Analog ground. Not connected inside the IC. Connect to ground via a capacitor of approximately 0.1 µF. Connect to analog power supply via a capacitor of approximately 0.1 µF. Not connected inside the IC. 10-bit DAC output. This pin outputs the luminance (Y) signal. Analog power supply. 10-bit DAC output. This pin outputs the B and V signals. Analog ground. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. 10-bit DAC output. This pin outputs the G and Y signals. Analog power supply. 10-bit DAC output. This pin outputs the R and U signals. Analog ground. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Digital power supply. —5— CXD1914Q Pin No. 82 83 84 85 86 87 88 89 90 91 92 93 94 TD8 TD9 TD10 XTEST1 XTEST2 XTEST3 XTEST4 XTEST5 VSS5 TDI TMS TDO TCK 95 TRST I 96 97 98 99 100 VDD5 NC NC NC NC — — — — — Symbol I/O Description I/O I/O I/O I I I I I — I I O I Test data I/Os. These pins should be open. In the test mode, these are used for the internal circuit test data bus. The test data bus is available only for the device vendor. Test mode control signal inputs. These pins are pulled up. When all these pins are “H”, the CXD1914Q is not in the test mode, but is in the normal mode. The test mode is available only for the device vendor. Digital ground. Test pin. Set “H”. This pin is pulled up. Test pin. Set “H”. This pin is pulled up. Test pin. This pin should be open. Test pin. Set “H”. Reset signal input for JTAG in active low. This pin is pulled up. Digital power supply. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. Not connected inside the IC. —6— CXD1914Q Electrical Characteristics DC Characteristics Item (Ta=0 to +70 °C, VSS=0 V) Symbol Input High voltage Input Low voltage VIH VIL Output High voltage VOH1 Output Low voltage VOL1 Output High voltage VOH2 Output Low voltage VOL2 Input leak current IIL1 Input leak current IIL2 Supply current IDD Measurement Measurement conditions Min. pins 2.2 ∗1 VDD=5.0 V ±5 % ∗1 VDD=5.0 V ±5 % IOH=–2.4 mA VDD–0.8 ∗2 VDD=4.75 to 5.25 V IOL=4.8 mA ∗2 VDD=4.75 to 5.25 V IOH=–1.2 mA ∗3 VDD–0.8 VDD=4.75 to 5.25 V IOL=2.4 mA ∗3 VDD=4.75 to 5.25 V VI=0 to 5.25 V ∗4 –10 VDD=4.75 to 5.25 V VI=0 V ∗5 –40 VDD=5.0 V ±5 % Typ. Max. Unit 0.8 V V V 0.4 V V –100 VDD=5.0 V ±5 % 0.4 V 10 µA –240 µA 85∗6 mA Note : ∗1 PD0-15, TD8-10, XTEST1-5, TRST, TDI, TMS,TCK, SI/SDA, SCK/SCL, XCS/SA, XVRST, XRST, SYSCLK, F1, XIICEN, TVSYNC, OSDSW, ROSD, GOSD, BOSD ∗2 PDCLK, VSYNC, HSYNC, FID, SO, CSYNC ∗3 TDO, TD0-10 ∗4 PD0-15, TD8-10, TCK, SI/SDA, SCK/SCL, XRST, F1, SYSCLK, TVSYNC, OSDSW,ROSD, GOSD, BOSD ∗5 XTEST1-5, TRST, TDI, TMS, XCS/SA, XVRST, XIICEN ∗6 Not including analog supply current (AVDD=5 V, R=200 Ω, VREF=2.00V , Ta=25 °C) DAC Characteristics 1 Item Resolution Linearity error Differential linearity error Output full-scale current Output offset voltage Output full-scale voltage Precision guaranteed output voltage range Symbol n EL ED IFS VOS VFS Measurement conditions VOC —7— Min. Typ. 10 2.0 2.0 1.0 10.5 1 2.1 Unit bit LSB LSB mA mV V 2.0 2.1 V –2.0 –1.0 9.5 10.0 1.9 1.9 Max. CXD1914Q AC Characteristics 1. Pixel data interface (1) 8-bit mode SYSCLK tPDS tPDH PD0-7 (Ta=0 to +70 °C, VDD=4.75 to 5.25 V, VSS=0 V) Item Pixel data setup time to SYSCLK Pixel data hold time to SYSCLK Symbol tPDS tPDH Min. 10 3 Typ. Max. Unit ns ns (2) 16-bit mode PDCLK tPDS tPDH PD0-15 (Ta=0 to +70 °C, VDD=4.75 to 5.25 V, VSS=0 V) Item Pixel data setup time to PDCLK Pixel data hold time to PDCLK Symbol tPDS tPDH —8— Min. 20 0 Typ. Max. Unit ns ns CXD1914Q 2. Serial port interface fSCK tPWHSCK tPWLSCK SCK tCSS tCSH XCS tSIS tSIH SI tSOD tSOH SO (Ta=0 to +70 °C, VDD=4.75 to 5.25 V, VSS=0 V) Item SCK clock rate SCK pulse width Low SCK pulse width High Chip select setup time to SCK Chip select hold time to SCK Serial input setup time to SCK Serial input hold time to SCK Serial output delay time from SCK Serial output hold time from SCK Symbol fSCK tPWLSCK tPWHSCK tCSS tCSH tSIS tSIH tSOD∗ tSOH∗ Min. DC 100 100 150 150 50 10 Typ. Max. 3 30 3 Unit MHz ns ns ns ns ns ns ns ns ∗CL=35 pF 3. XVRST, F1 SYSCLK tVS tVH XVRST F1 Item XVRST, F1 setup time to SYSCLK XVRST, F1 hold time to SYSCLK Symbol tVS tVH —9— Min. 10 0 Typ. Max. Unit ns ns CXD1914Q 4. SYSCLK, PDCLK, VSYNC, HSYNC, FID, CSYNC fSYSCLK tPWHCLK tPWLCLK SYSCLK tPDCLKD tPDCLKD PDCLK tCOD VSYNC, HSYNC, FID, CSYNC tCOH (Ta=0 to +70 °C, VDD=4.75 to 5.25 V, VSS=0 V) Item Symbol fSYSCLK tPWLCLK tPWHCLK tPDCLKD∗ tCOD∗ tCOH∗ SYSCLK clock rate SYSCLK pulse width Low SYSCLK pulse width High PDCLK delay time from SYSCLK Control output delay time from SYSCLK Control output hold time from SYSCLK Min. Typ. 27 Max. 11 11 20 25 3 Unit MHz ns ns ns ns ns ∗CL=35 pF —10— CXD1914Q Description of Functions The CXD1914Q converts digital parallel data (ITU-R601 Y, Cb, Cr) into analog TV signals in NTSC (RS170A) or PAL (ITU-R624; B, G, H, I) format. The CXD1914Q first receives image data in 8-bit parallel form (multiplexed Y, Cb, and Cr data), or in 16-bit parallel form (8-bit Y and 8-bit multiplexed Cb and Cr data). After demultiplexing, it converts the Cb and Cr signals into the U and V signals, respectively, interpolates 4 : 2 : 2 to 4 : 4 : 4, and then modulates the signals with the digital subcarrier inside the CXD1914Q to create the chroma (C) signal. The Y and chroma (C) signals are oversampled at double speed to reduce sin (X) / X roll-off, and then added to become the digital composite signal. The 10-bit DAC converts the digital composite, Y/C, U, V, and RGB signals into analog signals. 1. Pixel input format The pixel input format is selected according to the value (bit 4 of address 01H) of control register “PIF MODE” as shown in Table 1-1 below. When “PIF MODE” is “0”, the image data (multiplexed Y, Cb, and Cr data) input from PD0 to 7 are sampled at the rising edge of SYSCLK as shown in the chart on the following page. When “PIF MODE” is “1”, the image data (PD0 to 7 : Y data, PD8 to 15 : multiplexed Cb and Cr data) input from PD0 to 15 are sampled at the rising edge of PDCLK. PIF MODE 0 (8-bit mode) 1 (16-bit mode) PD15 to 8 N/A Cb/Cr PD7 to 0 Y/Cb/Cr Y Table 1-1 Also, the pixel input data timing is determined according to bits 3 and 2 (PIX TIM) of control register address 01H as shown in Table 1-2 below. When “PIF MODE” is “0", Cb0 of the image data (Cb0, Y0, Cr0 and Y1) input from PD0 to 7 is sampled at the rising edge of SYSCLK after the fall of HSYNC. (Default : Cb0 is sampled at the rising edge of the second SYSCLK after the fall of HSYNC.) When “PIF MODE” is “1”, Y0 and Y1 data are input to PD0 to 7, multiplexed Cb0 and Cr0 data are input to PD8 to 15, and Y0 and Cb0 are sampled at the respective rising edge of PDCLK after the fall of HSYNC. (Default : Y0 and Cb0 are sampled at the rising edge of the second PDCLK after the fall of HSYNC.) PIX TIM 0 0 1 1 0 1 0 1 Timing phase #0 (default) #1 #2 #3 Table 1-2 —11— CXD1914Q Pixel Data Input Timing 1 2 3 4 5 SYSCLK 1 2 3 PDCLK HSYNC [16-bit mode] PD0 to 7 Y0 Y1 Y2 Y3 Y4 Y5 Cb0 Cr0 Cb2 Cr2 Cb4 Cr4 Y0 Y1 Y2 Y3 Y4 Cb0 Cr0 Cb2 Cr2 Cb4 # 0 #1 PD8 to 15 # 2 #3 [8-bit mode] PD0 to 7 Cb0 #0 Y0 Cr0 Y1 Cb2 Y2 Cr2 Y3 Cb4 Y4 Cr4 Y5 Cb6 Cb0 Y0 Cr0 Y1 Cb2 Y2 Cr2 Y3 Cb4 Y4 Cb0 Y0 Cr0 Y1 Cb2 Y2 Cr2 Y3 Cb4 Y4 Cr4 Y0 Cr0 Y1 Cb2 Y2 Cr2 Y3 Cb4 Y4 Cr4 Y5 #1 #2 Cb0 #3 PD0 PD1 : PD7 Pixel data 0 (LSB) Pixel data 1 : Pixel data 7 (MSB) PD8 PD9 : PD15 —12— Pixel data 0 (LSB) Pixel data 1 : Pixel data 7 (MSB) CXD1914Q 2. Serial interface The CXD1914Q supports both the I2C bus (high-speed mode) and Sony serial interface modes. These modes can be selected by the XIICEN input pin as shown in Table 2-1 below. H SONY SIO Mode SI SCK XCS SO XIICEN SI/SDA SCK/SCL XCS/SA SO L Mode SDA SCL SA High-Z I2C Table 2-1 2-1 I2C bus interface The CXD1914Q becomes an I2C bus slave transceiver, and supports the 7-bit slave address and the high-speed mode (400 Kbits/s). 2-1-1. Slave address Two kinds of slave address (88H, 8CH) can be selected by the SA signal as shown in Table 2-2 below. A6 1 A5 0 A4 0 A3 0 A2 1 A1 SA A0 0 R/W X Table 2-2 A AAAAA AA AAAA AAAA AAAAA AA AAAAA A AA AAAA AAAA AAAAA AA A 2-1-2. Write cycle S Slave address W A start address A write data A write data A P ‘0’ from master to slave from slave to master D7 D6 D5 D4 Start address D3 D2 D1 D0 ADR [4 : 0] After the slave address is supplied from the master, the data in the next transfer cycle is set up inside the start address register of this IC as the start address of the control register. In subsequent cycles, the data supplied from the master is written in the addresses indicated by the control register address. The set control register address is automatically incremented with the completed transfer of each byte of data. —13— CXD1914Q A AAAAA AA AAAA AA AAAA AA AA AAAAA A AA AAAA AA AAAA AA AA A 2-1-3. Read cycle S Slave address R A read data A read data A P ‘1’ from master to slave from slave to master After the slave address is supplied from the master, subsequent cycles change immediately to read cycles and only the ID code (address 0CH, 0DH) is read out. During the read cycle, the start address is automatically set to 0CH. (Note) In the Sony SIO mode, addresses from 00H to 0DH can be read out. 2-1-4. Handling of the general call address (00H) The general call address is ignored and there is no ACK response. —14— CXD1914Q 2-2. Sony serial interface The Sony serial interface uses the SCK, XCS, SI and SO signals. The serial interface is active when the XCS signal is Low and transmits and receives signals to and from the host. The first byte after the XCS signal becomes Low is set up as a serial control command. Its data includes a control register address and read/write mode information for the interface. (See 2-2-1. Serial control command format.) The control register address is automatically incremented with the transfer of each byte of data. In the write mode, the SI signal of the serial input data is sampled at the rising edge of the SCK signal. In the read mode, the register value is read out as the SO signal of the serial output data at the falling edge of the SCK signal, and is variable. In this case, the SI signal of the serial input data is ignored. Serial Interface Timing SCK XCS D0 SI D1 D2 LSB D3 D4 D5 D6 D7 Serial Control Command D0 MSB D1 D2 D3 LSB D0 SO D4 D5 D6 Serial Data D1 D2 D3 D4 D7 MSB D5 D6 D7 Serial Interface Sequence SCK XCS 00H SI FFH 11H 00H CEH 01H 02H Internal address Control register address set Control Register Address 00H 01H 02H Control register address auto-increment Control register address auto-increment Control Register Data FFH 11H CEH 2-2-1. Serial control command format D7 D6 D5 D4 WR WR D3 D2 D1 D0 ADR [4 : 0] : Read/write mode When this bit is “1” : The serial interface is write mode, and the SI signal of the serial input data is written in the register. When this bit is “0” : The serial interface is read mode, and the register value is read out as the SO signal of the serial output data. ADR [4 : 0] : Control register address setting (Initial value of the address) —15— CXD1914Q 3. XVRST, F1 The XVRST and F1 signals are used to synchronize with the external V sync. The XVRST and F1 signals are sampled at the rising edge of SYSCLK, and the F1 signal is sampled when XVRST is Low. When F1 is High, the internal sync generator is reset to the 1st field, and when F1 is Low, it is reset to the 2nd field. When XVRST is set to High, the digital sync generator starts operation, and the sequence of the 1st or 2nd field starts. In the 16-bit mode, input XVRST with a width of four SYSCLK pulses at the rise of PDCLK. [8-bit mode] XVRST Timing (1st Field) SYSCLK XVRST F1 “H” Start of 1st field (NTSC : 4H) (PAL : 1H) Start of 2nd field (NTSC : 266H) (PAL : 313H) VSYNC F-ID HSYNC XVRST Timing (2nd Field) SYSCLK XVRST F1 “L” VSYNC F-ID 1/2H HSYNC —16— CXD1914Q [16-bit mode] XVRST Timing (1st Field) SYSCLK PDCLK XVRST F1 “H” Start of 1st field (NTSC : 4H) (PAL : 1H) VSYNC F-ID HSYNC XVRST Timing (2nd Field) SYSCLK PDCLK XVRST F1 “L” Start of 2nd field VSYNC F-ID 1/2H HSYNC —17— (NTSC : 266H) (PAL : 313H) CXD1914Q 4. Closed caption The CXD1914Q supports closed caption encoding. ASCII data for closed captions are encoded in line 21 and line 284 by adding a parity bit to every ASCII data set up in control registers 04H, 05H (data #1 and #2 for line 21) and 06H, 07H (data #1 and #2 for line 284). The control registers (04H to 07H) are double-buffered and ASCII data, which are set up by the serial interface, are synchronized with VSYNC. Automatic reset on/off can be selected for ASCII data which has been synchronized with VSYNC by changing the setting of bit 5 (CCRST) of control register address 03H. When CCRST=“1”, the control registers (04H, 05H or 06H, 07H) are automatically reset in sync with the rise of the next VSYNC. When CCRST=“0” (default), the control registers (04H, 05H or 06H, 07H) are not reset, and the data set last is held. Closed Caption Data Renewal Timing When CCRST=“1” Field 4 field 1 field VSYNC Control registers 04H and 05H set SI/SDA NEW DATA Data 21H Front-end buffer OLD DATA Data 21H Rear-end buffer Data 284H Front-end buffer NEW DATA OLD DATA DATA A (7’ h00) NEW DATA DATA RESET (7’h00) Data 284H Rear-end buffer Field DATA A (7’ h00) 1 field 2 field VSYNC Control registers 06H and 07H set SI/SDA NEW DATA Data 284H Front-end buffer OLD DATA Data 284H Rear-end buffer Data 21H Front-end buffer Data 21H Rear-end buffer NEW DATA OLD DATA DATA A (7’ h00) NEW DATA DATA RESET (7’h00) DATA A —18— (7’ h00) CXD1914Q When CCRST=“0” Field 4 field 1 field VSYNC Control registers 04H and 05H set SI/SDA NEW DATA Data 21H Front-end buffer OLD DATA NEW DATA Data 21H Rear-end buffe OLD DATA Data 284H Front-end buffer DATA A Data 284H Rear-end buffe DATA A Field NEW DATA 1 field 2 field VSYNC Control registers 06H and 07H set SI/SDA NEW DATA Data 284H Front-end buffer OLD DATA NEW DATA Data 284H Rear-end buffe OLD DATA Data 21H Front-end buffer DATA A Data 21H Rear-end buffe DATA A NEW DATA Double Buffer for Closed Caption SI 04H VSYNC Load ASCII data #1 Closed Caption Signal Waveform HSYNC Color Burst Clock Run-In Start Bits ASCII Data #1 ASCII Data #2 S1 S2 S3 b0 b1 b2 b3 b4 b5 b6 P1 b0 b1 b2 b3 b4 b5 b6 P2 50 IRE —19— CXD1914Q 5. VBID (Video ID) The CXD1914Q supports encoding of Video ID (Provisional Standard EIAJ CPX-1204) to discriminate the aspect ratio. VBID is 14-bit data as shown in Table 5-1, and becomes 20-bit data with the addition of 6-bit CRCC. These data are superimposed and output to lines 20 and 283 during the vertical blanking period of NTSC video signals. The data setting in Table 5-1 below is done by writing data in control registers (08H and 09H) via the serial interface. These control registers (08H and 09H) are double-buffered, and the VBID data are renewed in sync with the VSYNC signal. bit-No. A Word 0 B Word 1 Word 2 1 2 3 4 5 6 4-bit width 4-bit width Contents Transmission aspect ratio Image display format Undefined “1” “0” Full-mode (16 : 9) Letter-box 4:3 Normal Identification information about video and other signals (audio signals, etc.) incidental to image which are transmitted simultaneously Identification signal incidental to Word 0 Identification signal and information incidental to Word 0 Table 5-1 Double Buffer for VBID SI VSYNC 08H Load Word 0 VBID Data Renewal Timing VSYNC Control register 08H set SI NEW DATA Data #1 OLD DATA —20— NEW DATA CXD1914Q VBID Code Allocation The VBID data are composed of Word 0=6 bits (Word 0-A=3 bits and Word 0-B=3 bits), Word 1=4 bits, Word 2=4 bits, and CRCC=6 bits. bit 0… …bit 20 Data 0-A 0-B Word 1 4 bits Word 2 4 bits CRCC 6 bits Word 0 6 bits VBID Signal Waveform Ref. bit 1 bit 2 bit 3 … bit 20 2.235µs±20ns 11.2µs±0.6µs 49.1µs±0.5µs 1H 6. RGB/YUV output The CXD1914Q has an RGB/YUV output function. RGB and YUV can be switched by setting bit 2 (RGB_ UV) of control register address 03H. Also, the UV level can be selected from BetaCam or SMPTE by setting bit 0 (BTCM) of address 03H. During RGB output, when bit 1 (GSYNC) of control register address 03H is “1”, the sync signal is added to the G signal and output ; when bit 1 (GSYNC) is “0”, the sync signal is not added. 7. Support of interlace/non-interlace modes The CXD1914Q can be switched to the interlace and non-interlace modes by varying the setting of bit 1 (INTERLS) of control register address 01H. During the non-interlace mode, the 1st field is repeatedly output. Register setting value INTERLS 0 (non-interlace) 1 (interlace) Number of lines/field NTSC PAL 262 312 262.5 312.5 —21— CXD1914Q 8. WSS (Widescreen Signaling) The CXD1914Q supports WSS encoding to discriminate the aspect ratio. WSS is 14-bit data as shown in Table 6-1. These data are superimposed and output to line 23 during the vertical blanking period of PAL video signals. The data setting in Table 6-1 below is done by writing data in control registers (0AH and 0BH) via the serial interface. These control registers (0AH and 0BH) are double-buffered, and the WSS data are renewed in sync with the VSYNC signal. Group 1 Aspect ratio information (4 bits) b0-b3 0001 1000 0100 1101 0010 1011 0111 1110 Normal Letter-box 14 : 9 Letter-box 14 : 9 Letter-box 16 : 9 Letter-box 16 : 9 Letter-box >16 : 9 Full-mode 14 : 9 Full-mode 16 : 9 Group 2 PAL plus related information (4 bits) b4-b7 Center Top Center Top Center bit4 Camera/Film mode bit5-7 Reserved (Color plus) (Helper) (Baseband Helper) ∗ b3 is odd parity. Group 3 Subtitle information (3 bits) Group 4 Undefined (3 bits) b8-b10 bit8 TeleText subtitle enable/disable bit9, 10 00 No subtitle 10 Subtitle inside screen 01 Subtitle in black portion 11 Reserved b11-b13 Reserved Table 6-1 Double Buffer for WSS SI VSYNC 0AH Load Group 1, 2 WSS Data Renewal Timing VSYNC Control register 0AH set SI NEW DATA Data #1 OLD DATA —22— NEW DATA CXD1914Q WSS Signal Waveform bit 0 bit 1 bit 2 bit 3 649 … bit 13 71.4 IRE RUN -IN Start Code 256 0 IRE 20 11.03µs 10.67µs 16.59µs —23— —24— FID VSYNC HSYNC FID VSYNC HSYNC 261 524 262 525 263 3 264 265 Fields 2 and 4 2 266 4 267 5 268 3H 1 Vertical sync 3H 6 Vertical blanking Pre-equalization Fields 1 and 3 269 7 270 8 271 9 Post-equalization 3H 272 10 273 11 274 19 282 20 283 21 284 22 285 23 CXD1914Q Signal Waveform of NTSC Vertical Blanking Interval (Interlace mode) —25— Meander gate FID VSYNC HSYNC FID VSYNC HSYNC 620 (3) 309 308 622 (4) (1) (3) 621 (2) (4) 310 625 312 624 311 623 2.5H 2 3 Field 4 Field 3 Field 2 Field 1 315 316 Fields 2 and 4 313 314 1 2.5H Fields 1 and 3 4 317 2.5H 5 318 6 (3) 319 (2) 7 (1) (3) 320 (4) (2) 8 321 333 20 21 334 22 335 23 336 24 CXD1914Q Signal Waveform of PAL Vertical Blanking Interval (Interlace mode) —26— “0” FID “0” VSYNC HSYNC FID VSYNC HSYNC 261 523 263 1 264 Field 2 ∗1 2 265 3 266 4 267 5 268 6 269 7 270 8 3H 271 9 AA AA Post-equalization 272 10 273 11 ∗1 No differentiation is made between Fields 1 and 2 to facilitate the frame description. 262 524 3H AA Vertical sync 3H Vertical blanking Pre-equalization AA AA Field 1 ∗1 281 19 282 20 283 21 284 22 285 23 CXD1914Q Signal Waveform of NTSC Vertical Blanking Interval (Non-interlace mode) —27— FID VSYNC HSYNC FID VSYNC HSYNC “0” “0” 308 620 310 622 311 2H 623 312 624 2 314 2.5H Field 2 ∗1 313 1 2.5H 315 3 316 2.5H 4 2.5H 317 5 318 6 319 7 320 8 ∗1 No differentiation is made between Fields 1 and 2 to facilitate the frame description. 309 621 2H Field 1 ∗1 332 20 333 21 334 22 335 23 336 24 CXD1914Q Signal Waveform of PAL Vertical Blanking Interval (Non-interlace mode) CXD1914Q Sync Signal Timing 0.148µs 2.3µs 29.5µs 0.148µs 27.1µs 4.67µs 1/2H 63.555µs NTSC Equalizing Pulse and Sync Pulse Signal Waveform 0.296µs 2.37µs 29.63µs 0.296µs 27.3µs 4.67µs 1/2H 64µs PAL Equalizing Pulse and Sync Pulse Signal Waveform —28— CXD1914Q Control Register Map When “0” or “1” is indicated in the map, fix the respective bits to these values. BIT Function Selection #1 7 Address 00H FIDS 6 5 4 3 2 1 0 MASK EN PIX EN 0 BF SET UP 0 ENC MODE ENC MODE Encoding mode 0 : PAL encoding mode 1 : NTSC encoding mode (Default) SET UP Setup enable 0 : No setup level, black level=blanking level 1 : 7.5 IRE setup level insertion (Default) BF Burst flag enable 0 : Disable burst flag 1 : Enable burst flag (Default) PIX EN Pixel data enable 0 : Disable input pixel data 1 : Enable input pixel data (Default) MASK EN Mask enable 0 : Pixel data through during vertical blanking 1 : Pixel data reject during vertical blanking (Default) FIDS FID polarity select 0 : 1st field “H”, 2nd field “L” 1 : 1st field “L”, 2nd field “H” (Default) —29— R/W CXD1914Q BIT Function Selection #2 7 Address 01H DAC 6 5 4 3 PIF MODE MODE 2 PIX TIM 1 0 INTERLS 1 INTERLS 0 1 PIXTIM Pixel input timing 0 0 : #0 (Default) 0 1 : #1 1 0 : #2 1 1 : #3 PIF MODE Pixel input format 0 : 8-bit mode, multiplexed Y, Cb, Cr (4 : 2 : 2) (Default) 1 : 16-bit mode, Y and multiplexed Cb, Cr (4 : 2 : 2) DAC MODE DAC output activity 0 0 0 : Non-active 0 0 1 : Comp-Out active 0 1 0 : Inhibit 0 1 1 : Video signal (Y, C, Comp) -Out active (Default) 1 0 0 : Inhibit 1 0 1 : R, G, B-Out and Comp-Out active 1 1 0 : Inhibit 1 1 1 : All outputs active Function Selection #3 7 Address 02H 0 R/W : Non-interlace mode : Interlace mode (Default) 6 5 4 3 2 0 0 0 VBID WSS CC MODE Closed caption encoding mode 0 0 : Disable closed caption encoding (Default) 0 1 : Enable encoding in 1st field (Line 21) 1 0 : Enable encoding in 2nd field (Line 284) 1 1 : Enable encoding in both fields WSS WSS encoding enable 0 : Disable WSS encoding (Default) 1 : Enable WSS encoding VBID VBID encoding enable 0 : Disable VBID encoding (Default) 1 : Enable VBID encoding —30— 1 0 CC Mode R/W CXD1914Q BIT Function Selection #4 7 6 Address 03H 5 4 3 CCRST 0 0 BTCM UV output level control 0 : SMPTE 1 : BetaCam (Default) GSYNC GON SYNC enable 0 : Disable (Default) 1 : Enable RGB_UV RGB/YUV output mode switching 0 : YUV (Default) 1 : RGB CCRST Closed caption character RESET enable 0 : Disable (Default) 1 : Enable 2 1 RGB_UV GSYNC 0 BTCM R/W Closed Caption Character #1 (Line 21H) 7 6 5 Address 04H 4 3 ASCII Data #1 2 1 0 R/W (Default : 0H) Closed Caption Character #2 (Line 21H) 7 6 5 Address 05H 4 3 ASCII Data #2 2 1 0 R/W (Default : 0H) Closed Caption Character #1 (Line 284H) 7 6 5 Address 06H 4 3 ASCII Data #1 2 1 0 (Default : 0H) R/W Closed Caption Character #2 (Line 284H) 7 Address 07H 6 5 4 3 ASCII Data #2 —31— 2 1 (Default : 0H) 0 R/W CXD1914Q BIT VBID #1 7 6 5 Address 08H 4 3 2 1 0 Word 0 Word 0-B R/W Word 0-A VBID #2 7 Address 09H 6 5 4 3 Word 2 2 1 0 R/W Word 1 WSS #1 Address 0AH 7 6 5 4 3 2 1 0 bit 7 Group 2 bit 6 bit 5 bit 4 bit 3 bit 2 Group 1 bit 1 bit 0 7 6 5 4 3 2 1 0 bit 13 Group 4 bit 12 bit 11 bit 10 Group 3 bit 9 bit 8 5 4 3 2 1 0 R/W WSS #2 Address 0BH R/W Device ID #1 7 6 Address 0CH ID Code ID code RO (Lower) 14H Identification code : 14H Device ID #2 7 Address 0DH 6 5 4 3 ID Code ID code Identification code : 19H —32— 2 1 (Upper) 19H 0 RO CXD1914Q BLACK BLUE RED MAGENTA GREEN CYAN YELLOW WHITE Video Signal Timing (NTSC, 7.5 IRE Setup) 806 806 WHITE LEVEL 748 655 597 506 100 IRE 448 7.5 IRE 355 297 BLACK LEVEL BLANK LEVEL 256 40 IRE 36 SYNC LEVEL BLACK BLUE (±227) RED (±320) MAGENTA (±299) GREEN (±299) CYAN (±320) YELLOW (±227) WHITE NTSC Y (luminance) signal output waveform 7.5 IRE setup 832 622 20 IRE 512 BLANK LEVEL 402 COLOR BURST 192 NTSC C (chroma) signal output waveform 7.5 IRE setup —33— CXD1914Q BLACK BLUE RED MAGENTA GREEN CYAN YELLOW WHITE Video Signal Timing (NTSC, No Setup) 806 806 WHITE LEVEL 744 643 580 100 IRE 482 419 318 BLANK LEVEL 256 40 IRE 36 SYNC LEVEL BLACK BLUE (±245) RED (±347) MAGENTA (±324) GREEN (±324) CYAN (±347) YELLOW (±245) WHITE NTSC Y (luminance) signal output waveform 859 622 20 IRE 512 BLANK LEVEL 402 COLOR BURST 165 NTSC C (chroma) signal output waveform —34— CXD1914Q BLACK BLUE RED MAGENTA GREEN CYAN YELLOW WHITE Video Signal Timing (PAL) 806 806 WHITE LEVEL 744 643 580 100 IRE 482 419 318 BLANK LEVEL 256 43 IRE 20 SYNC LEVEL BLACK BLUE (±245) RED (±347) MAGENTA (±324) GREEN (±324) CYAN (±347) YELLOW (±245) WHITE PAL Y (luminance) signal output waveform 859 630 21.5 IRE 512 BLANK LEVEL 394 COLOR BURST 165 PAL C (chroma) signal output waveform —35— CXD1914Q CYAN GREEN MAGENTA RED BLUE BLACK 806 YELLOW R signal WHITE RGB Signal Output Waveform 806 806 257 257 805 805 256 256 WHITE LEVEL 100 IRE BLANK LEVEL CYAN GREEN MAGENTA RED BLUE BLACK 806 YELLOW G signal WHITE 256 806 807 806 806 256 256 256 256 WHITE LEVEL 100 IRE BLANK LEVEL 256 During GON SYNC (NTSC) 806 WHITE LEVEL 100 IRE BLANK LEVEL 256 40 IRE SYNC LEVEL 36 During GON SYNC (PAL) 806 WHITE LEVEL 100 IRE BLANK LEVEL 256 43 IRE SYNC LEVEL CYAN GREEN MAGENTA RED BLUE BLACK 806 YELLOW B signal WHITE 20 806 257 808 259 803 256 806 256 WHITE LEVEL 100 IRE 256 BLANK LEVEL —36— CXD1914Q UV Output Level Color Difference (U) Signal 782 BLUE 901 690 768 603 643 512 512 421 381 334 256 242 123 NTSC, No setup NTSC, No setup 761 871 677 750 596 633 512 512 428 391 347 274 263 153 NTSC, Setup NTSC, Setup 787 787 693 693 605 605 512 512 419 419 331 331 237 237 PAL PAL —37— BALCK RED MAGENTA GREEN YELLOW CYAN WHITE BALCK BLUE RED MAGENTA GREEN CYAN YELLOW BetaCam LEVEL WHITE SMPTE LEVEL CXD1914Q Color Difference (V) Signal 782 BLUE 901 738 838 555 574 512 512 469 450 286 186 242 123 NTSC, No setup NTSC, No setup 761 871 721 813 552 570 512 512 471 453 303 211 263 153 NTSC, Setup NTSC, Setup 787 787 742 742 556 556 512 512 468 468 282 282 237 237 PAL PAL —38— BALCK RED MAGENTA GREEN CYAN YELLOW WHITE BALCK BLUE RED MAGENTA GREEN YELLOW CYAN BetaCam LEVEL WHITE SMPTE LEVEL CXD1914Q Internal Filter Characteristics Interpolation Filter Characteristic 0 Attenuation [dB] –10 –20 –30 –40 –50 0 1 2 3 4 5 6 7 8 9 10 11 12 13 Frequency [MHz] Chrominance Filter Characteristic 0 Attenuation [dB] –20 –40 –60 –80 –100 0 1 2 3 4 5 6 Frequency [MHz] —39— 7 8 9 10 CXD1914Q DAC Application Circuit CXD1914Q AVDD VG 0.1µF VREF 1kΩ 3.2kΩ IREF AVSS Buff AMP LPF COMP-O Y-OUT C-OUT R/U-OUT G/Y-OUT B/V-OUT 0.1µF VB 75Ω 200Ω VSS Application Circuit CXD1914Q (Video encoder) MPEG decoder 8 PD0 to 7 PD0 to 7 FID FID HSYNC HSYNC VSYNC VSYNC CLK SYSCLK 27MHz Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. —40— CXD1914Q Package Outline Unit : mm 100PIN QFP (PLASTIC) 23.9 ± 0.4 + 0.4 20.0 – 0.1 + 0.1 0.15 – 0.05 80 51 + 0.4 14.0 – 0.1 17.9 ± 0.4 15.8 ± 0.4 50 81 A 31 100 1 0.65 30 + 0.15 0.3 – 0.1 0.13 + 0.2 0.1 – 0.05 + 0.35 2.75 – 0.15 M 0° to 10° DETAIL A 0.8 ± 0.2 (16.3) 0.15 PACKAGE STRUCTURE PACKAGE MATERIAL EPOXY RESIN SONY CODE QFP-100P-L01 LEAD TREATMENT SOLDER PLATING EIAJ CODE QFP100-P-1420 LEAD MATERIAL 42/COPPER ALLOY PACKAGE MASS 1.7g JEDEC CODE —41—