LMH0031 SMPTE 292M/259M Digital Video Deserializer / Descrambler with Video and Ancillary Data FIFOs General Description The LMH0031 SMPTE 292M / 259M Digital Video Deserializer/Descrambler with Video and Ancillary Data FIFOs is a monolithic integrated circuit that deserializes and decodes SMPTE 292M, 1.485Gbps (or 1.483Gbps) serial component video data, to 20-bit parallel data with a synchronized parallel word-rate clock. It also deserializes and decodes SMPTE 259M, 270Mbps, 360Mbps and SMPTE 344M (proposed) 540Mbps serial component video data, to 10-bit parallel data. Functions performed by the LMH0031 include: clock/data recovery from the serial data, serial-to-parallel data conversion, SMPTE standard data decoding, NRZI-to-NRZ conversion, parallel data clock generation, word framing, CRC and EDH data checking and handling, Ancillary Data extraction and automatic video format determination. The parallel video output features a variabledepth FIFO which can be adjusted to delay the output data up to 4 parallel data clock periods. Ancillary Data may be selectively extracted from the parallel data through the use of masking and control bits in the configuration and control registers and stored in the on-chip FIFO. Reverse LSB dithering is also implemented. The unique multi-functional I/O port of the LMH0031 provides external access to functions and data stored in the configuration and control registers. This feature allows the designer greater flexibility in tailoring the LMH0031 to the desired application. The LMH0031 is auto-configured to a default operating condition at power-on or after a reset command. Separate power pins for the PLL, deserializer and other functional circuits improve power supply rejection and noise performance. The LMH0031 has a unique Built-In Self-Test (BIST) and video Test Pattern Generator (TPG). The BIST enables comprehensive testing of the device by the user. The BIST uses the TPG as input data and includes SD and HD component video test patterns, reference black, PLL and EQ pathologicals and a 75% saturation, 8 vertical colour bar pattern, for all implemented rasters. The colour bar pattern has optional transition coding at changes in the chroma and luma bar data. The TPG data is output via the parallel data port. The LMH0030, SMPTE 292M / 259M Digital Video Serializer with Ancillary Data FIFO and Integrated Cable Driver, is the ideal complement to the LMH0031. The LMH0031’s internal circuitry is powered from +2.5 Volts and the I/O circuitry from a +3.3 Volt supply. Power dissipation is typically 850mW. The device is packaged in a 64-pin TQFP. Features n SDTV/HDTV serial digital video standard compliant n Supports 270 Mbps, 360 Mbps, 540 Mbps, 1.483 Gbps and 1.485 Gbps serial video data rates with auto-detection n LSB de-dithering option n Uses low-cost 27MHz crystal or clock oscillator reference n Fast VCO lock time: < 500 µs at 1.485 Gbps n Built-in self-test (BIST) and video test pattern generator (TPG)* n Automatic EDH/CRC word and flag processing n Ancillary Data FIFO with extensive packet handling options n Adjustable, 4-deep parallel output video data FIFO n Flexible control and configuration I/O port n LVCMOS compatible control inputs and clock and data outputs n LVDS and ECL-compatible, differential, serial inputs n 3.3V I/O power supply and 2.5V logic power supply operation n Low power: typically 850mW n 64-pin TQFP package n Commercial temperature range 0˚C to +70˚C * Patent applications made or pending. Applications n SDTV/HDTV serial-to-parallel digital video interfaces for: — Video editing equipment — VTRs — Standards converters — Digital video routers and switchers — Digital video processing and editing equipment — Video test pattern generators and digital video test equipment — Video signal generators Ordering Information Order Number Package Type NS Package Number LMH0031VS 64-Pin TQFP VEC-64A © 2006 National Semiconductor Corporation DS201796 www.national.com LMH0031 SMPTE 292M/259M Digital Video Deserializer / Descrambler with Video and Ancillary Data FIFOs January 2006 LMH0031 Typical Application 20179601 www.national.com 2 LMH0031 Block Diagram 20179602 3 www.national.com LMH0031 Connection Diagram 20179603 64-Pin TQFP Order Number LMH0031VS See NS Package Number VEC-64A www.national.com 4 CMOS Input Current (single input): It is anticipated that this device will not be offered in a military qualified version. If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office / Distributors for availability and specifications. Vi = VSSIO −0.15V: −5 mA Vi = VDDIO +0.15V: +5 mA ± 6 mA CMOS Output Source/Sink Current: IBB Output Current: +300 µA IREF Output Current: +300 µA CMOS I/O Supply Voltage (VDDIO–VSSIO): 4.0V SDI Supply Voltage (VDDSI–VSSSI): SDI Input Voltage (Vi): 4.0V Package Thermal Resistance Digital Logic Supply Voltage (VDDD–VSSD): 3.0V PLL Supply Voltage (VDDPLL–VSSPLL): 3.0V Storage Temp. Range: −65˚C to +150˚C CMOS Input Voltage (Vi): VSSIO −0.15V to VDDIO +0.15V Junction Temperature: +150˚C CMOS Output Voltage (Vo): VSSIO −0.15V to VDDIO +0.15V Lead Temperature (Soldering 4 Sec): +260˚C VSSSI −0.15V to VDDSI +0.15V θJA @ 0 LFM Airflow 40.1˚C/W θJA @ 500 LFM Airflow 24.5˚C/W θJC 5.23˚C/W ESD Rating (HBM): 6.0 kV ESD Rating (MM): 400 V Recommended Operating Conditions Symbol Parameter Conditions VDDIO CMOS I/O Supply Voltage VDDIO−VSSIO VDDSD SDI Supply Voltage VDDSI−VSSSI VDDD Digital Logic Supply Voltage VDDD–VSSD VDDPLL PLL Supply Voltage VDDPLL–VSSPLL TA Operating Free Air Temperature Reference Min Typ Max Units 3.150 3.300 3.450 V 2.375 2.500 2.625 V +70 ˚C Max Units 0 Required Input Conditions (Note 9) Symbol Parameter VIN Input Voltage Range t r , tf Rise Time, Fall Time Conditions Reference All LVCMOS Inputs 10%–90% Min VSSIO 1.0 SMPTE 259M, Level C Serial Input Data Rate VIN(SDI) SDI Serial Input Voltage, Single-ended VIN(SDI) SDI Serial Input Voltage, Differential t r , tf Rise Time, Fall Time V 3.0 ns 540 SDI, SDI MBPS 1,483 SMPTE 292M Common Mode Voltage VDDIO 360 SMPTE 344M SMPTE 292M VCM(SDI) 1.5 270 SMPTE 259M, Level D BRSDI Typ 1,485 VSSSI +1.0V VIN = 125 mVP-P SDI, SDI 20%–80%, SMPTE 259M Data Rates 20%–80%, SMPTE 292M Data Rates 5 VDDSI −0.05V V 125 800 880 mVP-P 125 800 880 mVP-P 0.4 1.0 1.5 ns 270 ps www.national.com LMH0031 Absolute Maximum Ratings (Note 1) LMH0031 Required Input Conditions (Continued) Symbol Conditions Parameter fACLK Ancillary / Control Data Clock Frequency DCACLK Duty Cycle, Ancillary Clock t r , tf Ancillary / Control Clock and Data Rise Time, Fall Time tS Setup Time, ADN to ACLK or ION to ACLK Rising Edge tH Hold Time, Rising Edge ACLK to ADN or ACLK to ION RREF Bias Supply Reference Resistor fEXT CLK External Clock Frequency fXTAL Crystal Frequency Reference ACLK 10%–90% Min Typ Max Units VCLK MHz 45 50 55 % 1.0 1.5 3.0 ns 3.0 1.5 ns 3.0 1.5 ns 4.75k Ω ION, ADN, ACLK Timing Diagram Control Data Input or I/O Bus Input Tolerance 1% Ext Clk Figure 6 XTALo, XTALi −100 ppm 27.0 +100 ppm MHz Max Units DC Electrical Characteristics Over Supply Voltage and Operating Temperature ranges, unless otherwise specified (Notes 2, 3). Symbol Parameter Conditions VIH Input Voltage High Level VIL Input Voltage Low Level IIH Input Current High Level VIH = VDDIO(Note 8) IIL Input Current Low Level VIL = VSSIO VOH Output Voltage High Level IOH = −2 mA VOL Output Voltage Low Level IOL = +2 mA VOHV Minimum Dynamic VOH IOH = −2 mA (Note 6) VOLP Maximum Dynamic VOL IOL = +2 mA (Note 6) VSDI Serial Data Input Voltage Reference All LVCMOS Inputs Min Typ 2.0 VDDIO VSSIO 0.8 +85 +150 −1 −20 2.4 2.7 VDDIO VSSIO VSSIO +0.3 VSSIO +0.5V All LVCMOS Outputs VSSIO +0.4 125 SDI, SDI 800 880 ±1 ± 10 ISDI Serial Data Input Current Input Thereshold Over VCM range IBB Bias Supply Output Current RBB = 8.66kΩ 1% −220 −188 Reference Output Current RREF = 4.75kΩ 1% −290 −262 IDD Power Supply Current, (3.3V) 3.3V Supply, Total IDD (2.5V) Power Supply Current, 2.5V Supply, Total www.national.com µA V VDDIO −0.5 VTH IREF V < 100 270MBPS Data Rate VDDIO, VDDSI 1,485MBPS Data Rate 270MBPS Data Rate VDDD, VDDPLL 1,485MBPS Data Rate 6 mVP-P µA mV µA 38.0 45.0 47.0 50.0 80 120 220 340 mA mA Over Supply Voltage and Operating Temperature ranges, unless otherwise specified (Note 3). Symbol Parameter Conditions Reference Min Typ Max Units Serial Video Data Inputs BRSDI Serial Input Data Rate SMPTE 259M, Level C 270 SMPTE 259M, Level D 360 SMPTE 344M 540 SMPTE 292M 1,483 SDI, SDI SMPTE 292M tr, tf Rise Time, Fall Time 20%–80%, SMPTE 259M Data Rates MBPS 1,485 0.4 1.0 20%–80%, SMPTE 292M Data Rates 1.5 ns 270 ps Parallel Video Data Outputs 27.0 SMPTE 259M, 270MBPS fVCLK Video Output Clock Frequency 36.0 SMPTE 267M, 360MBPS SMPTE 344M, 540MBPS VCLK 54.0 SMPTE 292M, 1,483MBPS 74.176 SMPTE 292M, 1,485MBPS tpd Propagation Delay, Video Clock to Video Data Valid DCV Duty Cycle, Video Clock 74.25 VCLK to DVN Timing Diagram 50%–50% 0.5 Video Data Output Clock Jitter 2.0 ns 50 ± 5 VCLK % 2.0 27MHz tJIT MHz 36MHz 1.4 VCLK 54MHz nsP-P 1.0 74.25MHz 0.5 Parallel Ancillary / Control Data Inputs, Multi-function Parallel Bus Inputs fACLK Ancillary / Control Data Clock Frequency DCA Duty Cycle, Ancillary Data Clock ANC Data clock (Note 7) tr, tf Output Rise Time, Fall Time 10%–90% tS Setup Time, ADN to ACLK or ION to ACLK Rising Edge Hold Time, Rising Edge ACLK to ADN or ACLK to ION tH VCLK MHz % ACLK Control Data Input or I/O Bus Input ION, ADN, ACLK Timing Diagram 45 50 55 1.0 1.5 3.0 3.0 1.5 3.0 1.5 ns Parallel Ancillary / Control Data Outputs tpd tpd Propagation Delay, Clock to Control Data Propagation Delay, Clock to Ancillary Data 8.5 ACLK to ADN Timing Diagram 50%–50% ns 11.5 Multi-function Parallel I/O Bus tr, tf Rise Time, Fall Time IO0–IO7 Timing Diagram 10%–90% 1.0 1.5 3.0 SD Rates (Note 5) 0.32 1.0 HD Rates (Note 5) 0.26 1.0 ns PLL/CDR, Format Detect tLOCK Lock Detect Time tFORMAT Format Detect Time All Rates ms 20 Note 1: “Absolute Maximum Ratings” are those parameter values beyond which the life and operation of the device cannot be guaranteed. The stating herein of these maximums shall not be construed to imply that the device can or should be operated at or beyond these values. The table of “Electrical Characteristics” specifies acceptable device operating conditions. 7 www.national.com LMH0031 AC Electrical Characteristics LMH0031 AC Electrical Characteristics (Continued) Note 2: Current flow into device pins is defined as positive. Current flow out of device pins is defined as negative. All voltages are referenced to VSSIO = VSSD = VSSSI = 0V. Note 3: Typical values are stated for VDDIO = VDDSI = +3.3V, VDDD = VDDPLL = +2.5V and TA = +25˚C. Note 4: Spec. is guaranteed by design. Note 5: Measured from rising-edge of first SDI cycle until Lock Detect bit goes high (true). Lock time includes CDR phase acquisition time plus PLL lock time. Note 6: VOHV and VOLP are measured with respect to reference ground. VOLP is the peak output LOW voltage or ground bounce that may occur under dynamic simultaneous output switching conditions. VOHV is the lowest output HIGH voltage or output droop that may occur under dynamic simultaneous output switching conditions. Note 7: When used to clock control data into or from the LMH0031, the duty cycle restriction does not apply. Note 8: IIH includes static current required by input pull-down devices. Note 9: Required Input Conditions are the electrical signal conditions or component values which shall be supplied by the circuit in which this device is used in order for it to produce the specified DC and AC electrical output characteristics. Note 10: Functional and certain other parametric tests utilize a LMH0030 as the input source to the SDI inputs of the LMH0031. The LMH0030 is DC coupled to the inputs of the LMH0031. Typical VIN = 800 mV, VCM = 2.9 V. Test Loads 20179604 www.national.com 8 LMH0031 Test Circuit 20179607 9 www.national.com LMH0031 Timing Diagram 20179608 VIDEO DATA PATH The Serial Data Inputs (SDI) accept serial video data at SMPTE 259M standard definition, SMPTE 344M (proposed) or SMPTE 292M high-definition data rates. These inputs accept standard ECL or LVDS signal levels and may be used single-ended or differentially. Inputs may be DC or AC coupled, as required, to devices and circuits supplying the data. Recommended operating conditions and all input DC and AC voltage and current specifications shall be observed when designing the input coupling circuits. For convenience, a reference bias source, pin name RREF, sets the reference current available from the input bias source, pin name RBB. The recommended nominal value of RREF is 4.75kΩ, 1%. RBB is provided so that the SDI inputs may be supplied DC bias voltage via external resistors when the inputs are AC-coupled. The bias source should be loaded with a resistance to the VSS supply. The source current available at RBB is 200µA. Figure 1 shows a typical input biasing scheme using RBB and RREF. Device Operation INTRODUCTION The LMH0031 SMPTE 292M/259M Digital Video Deserializer/Decoder is used in digital video signal origination and destination equipment: cameras, video tape recorders, telecines, editors, standards converters, video test and other equipment. It decodes and converts serial SDTV or HDTV component digital video signals into parallel format. The LMH0031 decoder/deserializer processes serial digital video (SDV) signals conforming to SMPTE 259M, SMPTE 344M (proposed) or SMPTE 292M and operates at serial data rates of 270 Mbps, 360 Mbps, 540 Mbps, 1.483 Gbps and 1.485 Gbps. Corresponding parallel output data rates are 27.0 MHz, 36.0 MHz, 54.0 MHz, 74.176MHz and 74.25 MHz. The LMH0031 accepts ECL or LVDS serial data input signals. Outputs signals are compatible with LVCMOS logic devices. Note: In the following explanations, these logical equivalences are observed: ON ≡ Enabled ≡ Set ≡ True ≡ Logic_1 and OFF ≡ Disabled ≡ Reset ≡ False ≡ Logic_0. www.national.com 10 clock. Interraction and operation of the character alignment control signals and indicators Framing Mode, Framing Enable and NSP (New Sync Position) is described later in this datasheet. (Continued) The LMH0031 implements TRS character LSB-clipping as prescribed in ITU-R BT.601. LSB-clipping causes all TRS characters with a value between 000h and 003h to be forced to 000h and all TRS characters with a value between 3FCh and 3FFh to be forced to 3FFh. Clipping is done after descrambling and de-dithering. Once the PLL attains lock, the video format detector processes the received data to determine the raster characteristics (video data format) and configure the LMH0031 to handle it. This assures that the parallel output data will be properly formatted, that the correct data rate is selected and that Ancillary Data and CRC/EDH data are correctly detected and checked. Supported parallel data formats or subformats may belong to any one of several component standards: SMPTE 125M, SMPTE 267M, SMPTE 260M, 274M, 295M or 296M. Refer to Table 4 for the supported formats. (See also the Section Application Information section for handling of other raster formats or format extensions developed after this device was designed). The detected video standard information is passed to the device control system and saved in the control registers from whence it may be read by the user. The LMH0031 may be configured to operate in a single video format by loading the appropriate FORMAT SET[4:0] control data into the FORMAT 0 control register. Also, the LMH0031 may be configured to handle only the standarddefinition data formats by setting the SD ONLY bit or only the high-definition data formats by setting the HD ONLY bit in the FORMAT 0 control register. When both bits are reset, the default condition, the part automatically detects the data rate and range. Aligned and de-processed parallel data passes into a variable-depth video FIFO prior to output. Video FIFO depth from 0 to 4 registers is set by a 3-bit word written into the VIDEO FIFO Depth[2:0] bits in the ANC 0 control register. The video FIFO permits adjustment of the parallel video data output timing or delay at a parallel word rate. The occurence of corresponding TRS indicator bits, EAV, SAV and NSP, in the control register corresponds to the input register position of the FIFO. This positioning permits a look-ahead function in which the alignment status of the video data can be determined up to four parallel clock periods prior to the appearance of that data at the parallel data output. The parallel video data is output on DV[19:0]. The 20-bit parallel video data is organized so that for HDTV data, the upper-order 10 bits DV[19:10] are luminance (luma) information and the lower 10 bits DV[9:0] are colour difference (chroma) information. SDTV data use the lower-order 10-bits DV[9:0] for both luma and chroma information. (The SDTV parallel data is also duplicated on DV[19:10]). VCLK is the parallel output word rate clock signal. The frequency of VCLK is appropriate to either the HD or SD data being processed. Data is valid between the falling edges of a VCLK cycle. Data may be clocked into external devices on the rising-edge of VCLK. The DV[19:0] and VCLK signals are LVCMOScompatible. 20179606 FIGURE 1. Optional Input Biasing Scheme The SMPTE descrambler receives NRZI serial data, converts it to NRZ, then decodes it to either 10-bit standard definition or 20-bit high definition parallel video data using the reverse polynomial X9 + X4 + 1 as specified in the respective standard: SMPTE 259M, SMPTE 344M (proposed) or SMPTE 292M. The data reception bit order is LSB-first. All data processing is done at the parallel rate. The LMH0031 incorporates circuitry that implements a method for handling data that has been subjected to LSB dithering. When so enabled, data from the de-scrambler is routed for de-dithering. The De-Dither Enable bit in the VIDEO INFO 0 control register enables this function. Dedithering of data present in the vertical blanking interval can be selectively enabled by use of the V De-Dither Enable bit in the VIDEO INFO 0 control register. The initial condition of De-Dither Enable and V De-Dither Enable is OFF. The descrambler supplies signals to theTRS character detector which identifies the presence of the valid video data. The TRS character detector processes the timing reference signals which control raster framing. TRS (sync) characters are detected and the video is aligned on word boundaries. Data is re-synchronized with the parallel word-rate 11 www.national.com LMH0031 Device Operation LMH0031 Device Operation immediately after the address is clocked into the port and before or simultaneously with the falling edge of ACLK at the end of that address cycle. Output data remains stable until the next rising edge of ACLK and may be written into external devices at any time after the removal of the address signal. This second clock resets the port from drive to receive and readies the port for another access cycle. Example: Read the Full-field Flags via the AD port. (Continued) ANCILLARY/CONTROL DATA PATH The 10-bit ancillary and Control Data Port AD[9:0] serves two functions in the LMH0031. Ancillary Data from the Ancillary Data FIFO is output from this port after its recovery from the video data stream. The utilization and flow of Ancillary Data from the device is managed by a system of control bits, masks and IDs stored in the control data registers. This port also provides read/write access to contents of the configuration and control registers. The signals RD/WR, ANC/ CTRL and ACLK control data flow through the port. 1. Set ANC/CTRL to a logic-low. 2. Set RD/WR to a logic-high. 3. Present 001h to AD[9:0] as the register address. 4. CONTROL DATA FUNCTIONS 5. 6. Release the bus driving the AD port. Read the data present on the AD port. The Full-field Flags are bits AD[4:0]. 7. Toggle ACLK to release the AD port. Figure 3 shows the sequence of clock and control signals for writing control data to the ancillary/control data port. The control data write mode is similar to the read mode. Control data write mode is invoked by making the ANC/CTRL input low and the RD/WR input low. The 8-bit address of the control register set to be accessed is input to the port on bits AD[7:0]. When a control register write address is being written to the port, AD[9:8] must be driven as 00b (0XXh, where XX are AD[7:0]). The address is captured on the rising edge of ACLK. The address data is removed on the falling edge of ACLK. Next, the control data is presented to the port bits AD[7:0] and written into the selected register on the next rising edge of ACLK. When control data is being written to the port, AD[9:8] must be driven as 11b (3XXh, where XX are AD[7:0]). Control data written into the registers may be read out non-destructively in most cases. Control data is input to and output from the LMH0031 using the lower-order 8 bits AD[7:0] of the ancillary/Control Data Port. This control data initializes, monitors and controls operation of the LMH0031. The upper two bits AD[9:8] of the port function as handshaking signals with the device accessing the port. When either a control register read or write address is being written to the port, AD[9:8] must be driven as 00b (0XXh, where XX are AD[7:0]). When control data is being written to the port, AD[9:8] must be driven as 11b (3XXh, where XX are AD[7:0]). When control data is being read from the port, the LMH0031 will output AD[9:8] as 10b (2XXh, where XX are output data AD[7:0]) and may be ignored by the monitoring system. Note: After either a manual or power-on reset, ACLK must be toggled three (3) times to complete initiallization of the Ancillary and Control Data Port. The sequence of clock and control signals for reading control data from the ancillary/control data port is shown in Figure 2. Control data read mode is invoked by making the ANC/ CTRL input low and the RD/WR input high. The 8-bit address of the control register set to be accessed is input to the port on bits AD[7:0]. To identify the data as an address, AD[9:8] must be driven as 00b. The complete address word will be 0XXh, where 0 is AD[9:8] and XX are AD[7:0]. The address is captured on the rising edge of ACLK. When control data is being read from the port, the LMH0031 will output AD[9:8] as 10b (2XXh, where XX are output data AD[7:0]) and may be ignored by the monitoring system. Data being output from the selected register is driven by the port immediately following the rising edge of ACLK or when the address signal is removed. For optimum system timing, the signals driving the address to the port should be removed www.national.com Toggle ACLK. Example: Setup (without enabling) the TPG Mode via the AD port using the 1125 line, 30 frame, 74.25MHz, interlaced component (SMPTE 274M) colour bars as test pattern. The TPG may be enabled after setup using the Multi-function I/O port or by the control registers. 1. Set ANC/CTRL to a logic-low. 2. Set RD/WR to a logic-low. 3. Present 00Dh to AD[9:0] as the Test 0 register address. 4. Toggle ACLK. 5. Present 327h to AD[9:0] as the register data. 6. Toggle ACLK. 12 LMH0031 Device Operation (Continued) 20179609 FIGURE 2. Control Data Read Timing (2 read and 1 write cycle shown) 20179610 FIGURE 3. Control Data Write Timing Ancillary Data Functions The LMH0031 can recover Ancillary Data from the serial data stream. This Ancillary Data and related control characters are defined in the relevant SMPTE standards and may reside in the horizontal and vertical blanking intervals. The data can consist of different types of message packets including audio data. The serial Ancillary Data space must be formatted according to SMPTE 291M. The LMH0031 supports Ancillary Data in the chrominance channel (C’r/ C’b) only for high-definition operation. Ancillary Data for standard definition follows the requirements of SMPTE 125M. The Ancillary Data FIFO is sized to handle a maximum length ANC data Type 1 or Type 2 packet without the ANC Flag, 259 words. Defined in SMPTE 291M, the packet con- sists of the Ancillary Data Flag, a 3-word Data ID and Data Count, 255 8- or 10-bit User Data Words and a Checksum. The design of the LMH0031 Ancillary Data FIFO also allows storage of up to 8 shorter length messages with total length not exceeding 259 words including all ID information. Ancillary Data is copied from the data stream into the Ancillary Data FIFO. The parallel Ancillary Data will still be present in the parallel chroma output DV[9:0]. ancillary flag information is not extracted into the FIFO. Copying of ANC data from the video data into the FIFO is controlled by the ANC Mask and ANC ID bits in the control registers. A system of flags, ANC FIFO Empty, ANC FIFO 90% Full, ANC FIFO Full and ANC FIFO Overrun are used to monitor FIFO status. The details and functions of these and other control words are explained later in this datasheet. 13 www.national.com LMH0031 Device Operation tied. Data may only be read from the port when in the Ancillary Data mode. Ancillary Data cannot be written to the port. To conserve power when the Ancillary Data function is not being used, the internal Ancillary Data FIFO clock is disabled. This clock must be enabled before Ancillary Data may be replicated into the FIFO for output. This internal FIFO clock is controlled by FIFO CLOCK ENABLE, bit-6 of the ANC 5 register (address 17h). The default condition of FIFO CLOCK ENABLE is OFF. After enabling the internal FIFO clock by turning this bit ON, ACLK must be toggled three (3) times to propagate the enable to the clock tree. (Continued) Figure 4 shows the relationship of clock, data and control signals for reading Ancillary Data from the port AD[9:0]. In Ancillary Data read mode, 10-bit Ancillary Data is routed from the Ancillary Data FIFO and read from the port AD[9:0] at a rate determined by ACLK. Ancillary Data read (output) mode is invoked by making the ANC/CTRL input high and the RD/WR input high. Ancillary Data is clocked from the FIFO on the L-H transition of ACLK. Data may be read from the port on rising edges of ACLK, after the specified propagation delay, until the FIFO is emp- 20179611 FIGURE 4. Ancillary Data Read Timing MULTI-FUNCTION I/O PORT The multi-function I/O port can be configured to provide immediate access to many control and indicator functions that are stored within the LMH0031’s configuration and control registers. The individual pins comprising this port are assigned as input or output for selected functions stored in the control data registers. The multi-function I/O port is configured by way of an 8x6-bit register bank consisting of registers I/O pin 0 CONFIG through I/O pin 7 CONFIG. The contents of these registers determine whether the port bits function as inputs or outputs and to which control function or indicator each port bit is assigned. Port bits may be assigned to access different functions and indicators or any or all port bits may be assigned to access the same function or indicator (output mode only). The same indicator or function should not be assigned to more than one port bit as an input. Controls and indicators that are accessible by the port and their corresponding selection addresses are given in the I/O Pin Configuration Register Addresses, Table 6. Table 2 gives the control register bit assignments. Data resulting from device operation will be sent to the selected I/O port bit. This same data is also stored in the configuration and control registers. Mapping the control and indicator functions in this manner means that device operation will be immediately reflected at the I/O port pins thereby ensuring more reliable real-time operation of the device within and by the host system. When a multifunction I/O port bit is used as input to a control register bit, data must be presented to the I/O port bit and clocked into the register bit using ACLK as shown in Figure 5. Port timing for bit write operations is the same as for the ANC/CTRL port operation. www.national.com 20179612 FIGURE 5. I/O Port Data Write Timing Example: Program multi-function I/O port bit-0 as the CRC Luma Error bit output. 1. Set ANC/CTRL to a logic-low. 2. Set RD/WR to a logic-low. 3. Present 00Fh to AD[9:0] as the I/O PIN 0 CONFIG register address. 4. Toggle ACLK. 5. Present 310h to AD[9:0] as the register data. 6. Toggle ACLK. EDH/CRC SYSTEM The LMH0031 has EDH and CRC character generation and checking circuitry. The EDH system functions as described in SMPTE Recommended Practice RP-165. The CRC system functions as specified in SMPTE 292M. The EDH/CRC polynomial generators/checkers accept parallel data from the de-serializing system and generate the EDH and CRC check words for comparison with those received in the data. The EDH Enable bit in the control register enables the EDH generation and checking system. Incoming SDTV data is checked for errors and the EDH flags are updated automati14 ness. PLL acquisition, data phase alignment and format detection time is 20ms or less at 1.485Mbps. The VCO has separate VDDPLL and VSSPLL power supply feeds, pins 51 and 52, which may be supplied power via an external lowpass filter, if desired. (Continued) cally. EDH errors are reported in the EDH0, EDH1, and EDH2 register sets of the configuration and control registers. Updated or new EDH check words and flags may be generated and inserted in the data. EDH check words are generated using the polynomial X16 + X12 + X6 + 1 per SMPTE RP165. Generation and automatic insertion of new or corrected EDH check words is controlled by EDH Force and EDH Enable bits in the control registers. EDH check words and status flags are inserted in the parallel data at the correct positions in the Ancillary Data space and formatted per SMPTE 291M. After a reset, the initial state of all EDH and CRC check characters is 00h. The SMPTE 292M high definition video standard employs CRC (cyclic redundancy check codes) error checking instead of EDH. The CRC consists of two 18-bit words generated using the polynomial X18 + X5 + X4 + 1 per SMPTE 292M. One CRC is used for luminance and one for chrominance data. The CRCs appear in the data stream following the EAV and line number characters. The CRCs are checked and errors are reported in the EDH0, EDH1, and EDH2 register sets of the configuration and control registers. 20179605 FIGURE 6. Crystal and Load Circuit A 27MHz crystal and load circuit may be used to provide the reference clock. A fundamental mode crystal with the following parameters is used: frequency 27MHz, frequency tolerance ± 30ppm, load capacitance 18pF, maximum drive level 100µW, equivalent series resistance < 50Ω, operating temperature range 0˚C to 70˚C. Refer to Figure 6 for a typical load circuit and connection information. The LMH0031 indicates that the PLL is locked to the incoming data rate and that the CDR has acquired a phase of the serial data by setting the Lock Detect bit in the Video Info 0 control register. Indication of the standard being processed is retained in the FORMAT[4:0] bits in the FORMAT 1 control data register. Format data from this register can be programmed for output on the multi-function I/O port. The power-on default assigns Lock Detect as I/O Port bit 4. PHASE-LOCKED LOOP / CLOCK-DATA RECOVERY SYSTEM The phase-locked loop and clock-data recovery (PLL/ CDR) system generates all internal timing and data rate clocks for the LMH0031. The PLL/CDR system consists of five main functional blocks: 1) the input buffer which receives the incoming data, 2) input data samplers which oversample the data coming from the input buffer, 3) a PLL (VCO, divider chain, phase-frequency detector and internal loop filter) which generates sampling and other system clocks, 4) a digital CDR system to recover the oversampled serial input data from the samplers and the digital system control and 5) a rate detect controller which sequences the PLL to find the data rate. Using an oversampling technique, the timing information encoded in the serial data is extracted and used to synchronize the recovered clock and data. The parallel data rate and other clock signals are derived from the regenerated serial clock. The parallel data rate clock is 1/10th of the serial data rate clock for standard definition or 1/20th of the serial data clock frequency for high definition. The data interface between the CDR and the digital processing block uses 10-bit data plus the required clocks. The PLL is held in coarse frequency lock by an external 27MHz clock signal, EXT CLK, or by an external 27MHz crystal and internal oscillator. Upon power-on, EXT CLK is the default reference. The internal oscillator and an external crystal may be used as the reference by setting the OSCEN bit in the CDR register. The reference clock reduces lock latency and enhances format and auto-rate detection robust- POWER SUPPLIES, POWER-ON-RESET AND RESET INPUT The LMH0031 requires two power supplies, 2.5V for the core logic functions and 3.3V for the I/O functions. The supplies must be applied to the device in proper sequence. The 3.3V supply must be applied prior to or coincident with the 2.5V supply. Application of the 2.5V supply must not precede the 3.3V supply. It is recommended that the 3.3V supply be configured or designed so as to control application of the 2.5V supply in order to satisfy this sequencing requirement. The LMH0031 has an automatic, power-on-reset circuit. Reset initializes the device and clears TRS detection circuitry, all latches, registers, counters and polynomial generators/checkers and resets the EDH/CRC characters to 00h. An active-HIGH-true, manual reset input is available at pin 49. The reset input has an internal pull-down device and may be considered inactive when unconnected. Important: When power is first applied to the device or following a reset, the ancillary and Control Data Port must be initialized to receive data. This is done by toggling ACLK three times. 15 www.national.com LMH0031 Device Operation LMH0031 Device Operation selection of the desired HD test pattern is sufficient to enable the device to configure itself to run at the correct rate and generate valid data. Table 5 gives the available test patterns and codes. (Continued) TEST PATTERN GENERATOR (TPG) AND BUILT-IN SELF-TEST (BIST) The LMH0031 includes an on-board, parallel video test pattern generator (TPG). Four test pattern types are available in both HD and SD formats, NTSC and PAL standards, and 4x3 and 16x9 raster sizes. The test patterns are: flat-field black, PLL pathological, equalizer (EQ) pathological and a 75%, 8-colour vertical bar pattern. The pathologicals follow recommendations contained in SMPTE RP 178-1996 regarding the test data used. The colour bar pattern has optional bandwidth limiting coding in the chroma and luma data transitions between bars. The VPG FILTER ENABLE bit in the VIDEO INFO 0 control register enables the colour bar filter function. The test pattern data is available at the video data outputs, DV[19:0] with a corresponding parallel rate clock, VCLK, appropriate to the particular standard and format selected. The TPG also functions as a built-in self-test (BIST) which can be used to verify device functionality. The BIST function performs a comprehensive go/no-go test of the device. The test may be run using any of the HD colour bar patterns or one of two SD patterns, either the 270 Mb/s NTSC colour bar or the PAL PLL pathological, as the test data pattern. Data is input from the digital processing block, processed through the device and tested for errors using either the EDH system for SD or the CRC system for HD. Clock signals from the CDR block supply timing for the test data. The CDR must be supplied a 27MHz reference clock via the XTALi/Ext Clk input (or using the internal oscillator and crystal) during the TPG or BIST function. A go/no-go indication is logged in the Pass/Fail bit of the TEST 0 control register set. This bit may be assigned as an output on the multifunction I/O port. TPG and BIST operation is initiated by loading the code for the desired test pattern into the Test Pattern Select[5:0] bits and by setting the TPG Enable bit of the TEST 0 register. Note that when attempting to use the TPG or BIST immediately after the device has been reset or powered on, the TPG defaults to the 270Mbps SD rate. The device must be configured for the desired test pattern by loading the appropriate code in to the TEST 0 register. If HD operation is desired, www.national.com The Pass/Fail bit in the control register gives the device test status indication. If no errors have been detected, this bit will be set to logic-1 approximately 2 field intervals after TPG Enable is set. If errors have been detected in the internal circuitry of the LMH0031, Pass/Fail will remain reset to a logic-0. TPG or BIST operation is stopped by resetting the TPG Enable bit. Parallel output data is present at the DV[19:0] outputs during TPG or BIST operation. Example: Enable the TPG Mode to use the NTSC 270Mbps colour bars as the BIST and TPG pattern. Enable TPG operation using the I/O port. 1. 2. 3. Set ANC/CTRL to a logic-low. Set RD/WR to a logic-low. Present 00Dh to AD[9:0] as the TEST 0 register address. 4. Toggle ACLK. 5. Present 343h to AD[9:0] as the register data (525 line, 30 frame, 27MHz, NTSC 4x3, colour bars (SMPTE 125M)). 6. Toggle ACLK. 7. The PASS/FAIL indicator, TEST 0 register, Bit 7, should be read for the result of the test. Alternatively, this bit may be mapped to a convenient bit of the Multi-function I/O bus. The test pattern data and clock is available at the DV[19:0] and VCLK outputs. CONFIGURATION AND CONTROL REGISTERS The configuration and control registers store data which determines the operational modes of the LMH0031 or which result from its operation. Many of these registers may be assigned as external I/O functions which are then available on the multi-function I/O bus. These functions are summarized in Table 1 and detailed in Table 2. The power-on default condition for the multi-function I/O port is indicated in Table 1 and detailed in Table 6. 16 LMH0031 Device Operation (Continued) TABLE 1. Configuration and Control Data Register Summary Bits Read or Write Initial Condition Available on I/O Bus CRC Error (SD/HD) 1 R Reset Output CRC Error Luma 1 R Reset Output CRC Error Chroma 1 R Reset Output CRC Replace 1 R/W OFF No Full-Field Flags 5 R Reset No Active Picture Flags 5 R Reset No ANC Flags 5 R Reset No EDH Force 1 R/W OFF Input EDH Enable 1 R/W ON Input F/F Flag Error 1 R Reset Output A/P Flag Error 1 R Reset Output ANC Flag Error 1 R Reset Output ANC Checksum Force 1 R/W OFF Input ANC Checksum Error 1 R Reset Output ANC FIFO Empty 1 R Set Output ANC FIFO 90% Full 1 R Reset Output Register Function Notes EDH and CRC Operations (Note 11) I/O 5 (Note 13) Ancillary Data Operations (Note 11) I/O 6 ANC FIFO Full 1 R Reset Output ANC FIFO Overrun 1 R Reset Output ANC ID 16 R/W 0000h No ANC Mask 16 R/W FFFFh No MSG Track 1 R/W OFF No MSG Flush Static 1 R/W OFF No FIFO Flush Static 1 R/W OFF No Full MSG Available 1 R OFF Output Short MSG Detect 1 R OFF Output FIFO Clock Enable 1 R/W OFF No FIFO Extract Enable 1 R/W OFF Input 3 R/W 000b No Format Set 5 R/W 00000B No SD Only 1 R/W OFF No HD Only 1 R/W OFF Format 5 R Output Format [4] (Note 11) I/O 3 H 1 R Output (Note 11) I/O 2 V 1 R Output (Note 11) I/O 1 F 1 R Output (Note 11) I/O 0 Framing Mode 1 R/W ON Framing Enable 1 R/W ON New Sync Position (NSP) 1 R Output SAV 1 R Output Video FIFO Operation Video FIFO Depth Video Format Operations No No Input EAV 1 R De-scramble Enable 1 R/W ON Output No NRZI Enable 1 R/W ON No 17 (Note 11) I/O 7 www.national.com LMH0031 Device Operation (Continued) TABLE 1. Configuration and Control Data Register Summary (Continued) Bits Read or Write Initial Condition Available on I/O Bus LSB Clipping Enable 1 R/W ON No Sync Detect Enable 1 R/W ON No De-Dither Enable 1 R/W OFF Input Vert. De-Dither Enable 1 R/W OFF Lock Detect 1 R Unscrambled Video Data Out 1 R/W OFF No Test Pattern Select 6 R/W 000000b Input TPG Enable 1 R/W OFF Input Register Function Notes Input Output (Note 11) I/O 4 (Note 13) TPG and BIST Operations Pass/Fail 1 R VPG Filter Enable 1 R/W Reference Clock 2 External Vclk 1 525/27 MHz/Black Output OFF Input R/W 00b No EXT CLK Enabled R/W OFF No (Note 13) R/W See Table 6 No Reference Clock Operations Multifunction I/O Bus Operations I/O Bus Pin Config. 48 Note 11: Connected to multifunction I/O port at power-on. Note 12: ON = SET = logic-1, OFF = RESET = logic-0 (positive logic). Note 13: Special or restricted functionality. Refer to text for details. TABLE 2. Control Register Bit Assignments Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 EDH ENABLE F/F UES F/F IDA F/F IDH F/F EDA F/F EDH CRC ERROR CHROMA A/P UES A/P IDA A/P IDH A/P EDA A/P EDH ANC FLAG ERROR ANC UES ANC IDA ANC IDH ANC EDA ANC EDH ANC FIFO OVERRUN ANC FIFO EMPTY ANC FIFO FULL ANC ID(5) ANC ID(4) ANC ID(3) ANC ID(2) ANC ID(1) ANC ID(0) ANC ID(13) ANC ID(12) ANC ID(11) ANC ID(10) ANC ID(9) ANC ID(8) ANC MASK(5) ANC MASK(4) ANC MASK(3) ANC MASK(2) ANC MASK(1) ANC MASK(0) ANC MASK(14) ANC MASK(13) ANC MASK(12) ANC MASK(11) ANC MASK(10) ANC MASK(9) ANC MASK(8) reserved FIFO FLUSH STATIC reserved MSG FLUSH STATIC MSG TRACK EDH 0 (register address 01h) CRC ERROR EDH FORCE EDH 1 (register address 02h) CRC REPLACE CRC ERROR LUMA EDH 2 (register address 03h) F/F FLAG ERROR A/P FLAG ERROR ANC 0 (register address 04h) VIDEO VIDEO VIDEO FIFO-DEPTH(2) FIFO-DEPTH(1) FIFO-DEPTH(0) ANC CHECK- ANC CHECKSUM ERROR SUM FORCE ANC 1 (register address 05h) ANC ID(7) ANC ID(6) ANC 2 (register address 06h) ANC ID(15) ANC ID(14) ANC 3 (register address 07h) ANC MASK(7) ANC MASK(6) ANC 4 (register address 08h) ANC MASK(15) ANC 5 (register address 17h) FIFO EXTRACT ENABLE www.national.com FIFO CLOCK ENABLE FULL MSG AVAILABLE 18 (Continued) TABLE 2. Control Register Bit Assignments (Continued) Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 ANC PARITY MASK reserved reserved reserved reserved VANC HD ONLY FORMAT SET(4) FORMAT SET(3) FORMAT SET(2) FORMAT SET(1) FORMAT SET(0) H FORMAT(4) FORMAT(3) FORMAT(2) FORMAT(1) FORMAT(0) TEST PATTERN SELECT(5) TEST PATTERN SELECT(4) TEST PATTERN SELECT(3) TEST PATTERN SELECT(2) TEST PATTERN SELECT(1) TEST PATTERN SELECT(0) LOCK DETECT EAV SAV NSP FRAMING ENABLE LSB CLIP ENABLE reserved NRZI ENABLE DE-Scramble ENABLE reserved reserved reserved INT_OSC EN CLK EN reserved PIN 0 SEL[4] PIN 0 SEL[3] PIN 0 SEL[2] PIN 0 SEL[1] PIN 0 SEL[0] PIN 1 SEL[4] PIN 1 SEL[3] PIN 1 SEL[2] PIN 1 SEL[1] PIN 1 SEL[0] PIN 2 SEL[4] PIN 2 SEL[3] PIN 2 SEL[2] PIN 2 SEL[1] PIN 2 SEL[0] PIN 3 SEL[4] PIN 3 SEL[3] PIN 3 SEL[2] PIN 3 SEL[1] PIN 3 SEL[0] PIN 4 SEL[4] PIN 4 SEL[3] PIN 4 SEL[2] PIN 4 SEL[1] PIN 4 SEL[0] PIN 5 SEL[4] PIN 5 SEL[3] PIN 5 SEL[2] PIN 5 SEL[1] PIN 5 SEL[0] PIN 6 SEL[4] PIN 6 SEL[3] PIN 6 SEL[2] PIN 6 SEL[1] PIN 6 SEL[0] PIN 7 SEL[4] PIN 7 SEL[3] PIN 7 SEL[2] PIN 7 SEL[1] PIN 7 SEL[0] ANC 6 (register address 18h) ANC FIFO 90% FULL SHORT MSG DETECT FORMAT 0 (register address 0Bh) FRAMING MODE SD ONLY FORMAT 1 (register address 0Ch) F V TEST 0 (register address 0Dh) PASS/FAIL TPG ENABLE VIDEO INFO 0 (register address 0Eh) DE-DITHER ENABLE VERT. DE-DITHER ENABLE VPG FILTER ENABLE VIDEO CONTROL 0 (register address 55h) reserved EXTERNAL VCLK SYNC DETECT ENABLE REFERENCE CLOCK (register address 67h) reserved reserved reserved MULTI-FUNCTION I/O BUS PIN CONFIGURATION I/O PIN 0 CONFIG (register address 0Fh) reserved reserved PIN 0 SEL[5] I/O PIN 1 CONFIG (register address 10h) reserved reserved PIN 1 SEL[5] I/O PIN 2 CONFIG (register address 11h) reserved reserved PIN 2 SEL[5] I/O PIN 3 CONFIG (register address 12h) reserved reserved PIN 3 SEL[5] I/O PIN 4 CONFIG (register address 13h) reserved reserved PIN 4 SEL[5] I/P PIN 5 CONFIG (register address 14h) reserved reserved PIN 5 SEL[5] I/O PIN 6 CONFIG (register address 15h) reserved reserved PIN 6 SEL[5] I/O PIN 7 CONFIG (register address 16h) reserved reserved PIN 7 SEL[5] 19 www.national.com LMH0031 Device Operation LMH0031 Device Operation Specific types of CRC errors in incoming HD serial data are reported in the CRC ERROR LUMA and CRC ERROR CHROMA bits. (Continued) TABLE 3. Control Register Addresses Register Name The CRC REPLACE bit, when set, causes the CRCs in the incoming data to be replaced with CRCs calculated by the LMH0031. The bit is normally reset (OFF). Address Hexadecimal EDH 0 01 EDH 1 02 EDH 2 03 ANC 0 04 ANC 1 05 ANC 2 06 ANC 3 07 ANC 4 08 ANC 5 17 ANC 6 18 FORMAT 0 0B FORMAT 1 0C TEST 0 0D VIDEO INFO 0 0E I/O PIN 0 CONFIG 0F I/O PIN 1 CONFIG 10 I/O PIN 2 CONFIG 11 I/O PIN 3 CONFIG 12 I/O PIN 4 CONFIG 13 I/O PIN 5 CONFIG 14 I/O PIN 6 CONFIG 15 I/O PIN 7 CONFIG 16 VIDEO CONTROL 0 55 VIDEO CONTROL 1 56 REFERENCE CLOCK 67 EDH 2 (register 03h) The EDH Ancillary Data flags ANC UES, ANC IDA, ANC IDH, ANC EDA andANC EDH are defined in SMPTE RP 165. The flags are updated automatically when the EDH function is enabled and data is being received. The status of EDH flag errors in incoming SD serial data are reported in the ffFlagError, apFlagError and ancFlagError bits. Each of these bits is the logical-OR of the corresponding EDH and EDA flags. ANC 0 (Address 04h) The V FIFO Depth[2:0] bits control the depth of the video FIFO which preceeds the parallel output data drivers. The depth can be set from 0 to 4 stages by writing the corresponding binary code into these bits. For example: to set the Video FIFO depth at two registers, load 11010XXXXXb into the ANC 0 control register (where X represents the other functional bits of this register). Note: When changing some but not all bits in a register and to retain unchanged other data previously stored in the register, read the register’s contents and logically-OR this with the new data. Then write the modified data back into the register. Flags for ANC FIFO EMPTY, ANC FIFO 90% FULL, ANC FIFO FULL and ANC FIFO OVERRUN are available in the configuration and control register set. These flags can also be assigned as outputs on the multi-function I/O port. ANC FIFO EMPTY when set indicates that the FIFO contains no data. ANC FIFO 90% FULL indicates when the FIFO is at 90% of capacity. Since it is virtually impossible for the host processor to begin extracting data from the FIFO after it has been flagged as full without the possibility of an overrun condition occurring, ANC FIFO 90% FULL is used as an advanced command to the host to begin extracting data from the FIFO. To be used properly, ANC FIFO 90% FULL should be assigned as an output on the multi-function I/O port and monitored by the host system. Otherwise, inadvertent loss of ancillary packet data could occur. ANC FIFO FULL when set indicates that the FIFO registers are completely filled with data. The ANC FIFO OVERRUN flag indicates that an attempt to write data into a full FIFO has occurred. ANC FIFO OVERRUN can be reset by reading the bit’s status via the ancillary/ Control port. If an overrun occurrs, the status of the FIFO message tracking will be invalidated. In this event, the FIFO should be flushed to reset the message tracking pointers. Any messages then in the FIFO will be lost. The ANC Checksum Force bit, under certain conditions, enables the overwriting of Ancillary Data checksums received in the data. Calculation and insertion of new Ancillary Data checksums is controlled by the ANC Checksum Force bit. If a checksum error is detected (calculated and received checksums do not match) and the ANC Checksum Force bit is set, the ANC Checksum Error bit is set and a new checksum is inserted in the Ancillary Data replacing the previous one. If a checksum error is detected and the ANC Checksum Force bit is not set, the checksum mismatch is EDH 0 (register 01h) The EDH Full-Field flags F/F UES, F/F IDA, F/F IDH, F/F EDA andF/F EDH are defined in SMPTE RP 165. The flags are updated automatically when the EDH function is enabled and data is being received. The EDH ENABLE bit, when set, enables operation of the EDH generator function during SD operation. The default condition of this bit is set (ON). The EDH FORCE bit, when set, causes updated EDH packets to be inserted in the parallel output data regardless of the previous condition of EDH checkwords and flags in the input serial data. This function may be used in situations where video content has been edited thus making the previous EDH information invalid. The default condition of this bit is reset (OFF). The CRC ERROR bit indicates that errors in either the EDH checksums (SD) or CRC checkwords (HD) were detected in the serial input data. This bit is a combined function which indicates the presence of either EDH errors during SD operation or CRC errors during HD operation. EDH 1 (register 02h) The EDH Active Picture flags A/P UES, A/P IDA, A/P IDH, A/P EDA andA/P EDH are defined in SMPTE RP 165. The flags are updated automatically when the EDH function is enabled and data is being received. www.national.com 20 FIFO are FIFO FLUSH STAT and MSG FLUSH STAT. If the user wishes to handle more than 8 messages, the MSG TRACK bit should be turned off (reset). The operation FIFO FLUSH STAT will no longer work and the function FULL MSG AVAILABLE will no longer be a reliable indicator that messages are available in the FIFO. The user may still effectively use the FIFO by monitoring the states of ANC FIFO EMPTY, ANC FIFO FULL, ANC FIFO 90%FULL and ANC FIFO OVERRUN. (Continued) reported via the ANC Checksum Error bit. ANC Checksum Error is available as an output on the multifunction I/O port. ANC 1 AND 2 (Addresses 05h and 06h) The extraction of Ancillary Data packets from video data into the FIFO is controlled by the ANC MASK[15:0] and ANC ID[15:0] bits in the control registers. The ANC ID[7:0] register normally is set to a valid 8-bit code used for component Ancillary Data packet DID identification as specified in SMPTE 291M-1998. Similarly, ANC ID[15:8] normally is set to a valid 8-bit code used for component Ancillary Data packet SDID/DBN identification. Setting the FIFO FLUSH STAT bit to a logic-1 flushes the FIFO. FIFO FLUSH STAT may not be set while the FIFO is being accessed (Read or Write). FIFO FLUSH STAT is automatically reset after this operation is complete. When MSG FLUSH STAT is set to a logic-1, the oldest message packet in the FIFO is flushed when data is not being written to the FIFO. MSG FLUSH STAT is automatically reset after this operation is complete. The FULL MSG AVAILABLE bit in the control registers, when set, notifies the host system that complete packets reside in the Ancillary Data FIFO. When this bit is not set, the messages in the FIFO are incomplete or partial. This function is not affected by MSG TRACK. The FULL MSG AVAILABLE function is most useful when mapped to the multifunction I/O port as an output. ANC 3 AND 4 (Addresses 07h and 08h) The ANC MASK[7:0] is an 8-bit word that can be used to selectively control extraction of packets with specific DIDs (or DID ranges) into the FIFO. When the ANC MASK[7:0] is set to FFh, packets with any DID can be extracted into the FIFO. When any bit or bits of the ANC MASK[7:0] are set to a logic-1, the corresponding bit or bits of the ANC ID[7:0] are a don’t-care when matching DIDs of packets being extracted. When the ANC MASK[7:0] is set to 00h, the ANC DID of incoming packets must match exactly, bit-for-bit the ANC ID[7:0] set in the control register for the packets to be extracted into the FIFO. The initial value of the ANC MASK[7:0] is FFh and the ANC ID[7:0] is 00h. ANC 6 (Address 18h) The ANC FIFO 90% FULL flag bit indicates when the ANC FIFO is 90% full. This bit may be mapped to the multifunction I/O port. The purpose of this flag is to provide a signal which gives the host system time to begin reading from the FIFO before it has the chance to overflow. This was done because it is virtually impossible to monitor the FIFO FULL flag and begin extracting from the FIFO before an overrun condition occurs. Similarly, ANC MASK[15:8] is an 8-bit word that can be used to selectively control extraction of packets with specific SDID/DBN (or SDID/DBN ranges) into the FIFO. Operation and use of these bits is the same as for ANC MASK[7:0] previously discussed. ANC 5 (Address 17h) The FIFO EXTRACT ENABLE bit in the control registers enables the device to extract or copy Ancillary Data from the video data stream and place it in the ANC FIFO. From there data may be output via the parallel ancillary port. Data extraction is enabled when this bit is set to a logic-1. This bit can be used to delay automatic extraction and therefore the output of parallel Ancillary Data. FIFO EXTRACT ENABLE should be asserted during an SAV or EAV to avoid timing problems with Ancillary Data extraction. Access to data in the FIFO is controlled by the RD/WR, ANC/CTRL and ACLK control signals. To conserve power when the Ancillary Data function is not being used, the internal Ancillary Data FIFO clock is disabled. This clock must be enabled before Ancillary Data may be replicated into the FIFO for output. FIFO CLOCK ENABLE, bit-6 of the ANC 5 register (address 17h), when set, enables this clock to propagate to the FIFO. The default condition of FIFO CLOCK ENABLE is OFF. After enabling the internal FIFO clock by turning this bit ON, ACLK must be toggled three (3) times to propagate the enable to the clock tree. ACLK should remain running at all times when the ANC FIFO is in use. Otherwise, message tracking and related functions will not operate correctly. The LMH0031 can keep track of up to 8 ANC data packets in the ANC FIFO. Incoming packet length versus available space in the FIFO is also tracked. The MSG TRACK bit in the control registers, when set, enables tracking of packets in the FIFO. Other functions for control of packet traffic in the The SHORT MSG DETECT flag bit indicates when short ANC messages have been detected. i.e. An ANC header was detected before the last full message was recovered. This bit may be mapped to the multi-function I/O port. The ANC PARITY MASK bit when set disables parity checking for DID and SDID words in the ANC data packet. When reset, parity checking is enabled; and, if a parity error occurs, the packet will not be extracted. The VANC bit, when set, enables extraction of ANC data present in the vertical blanking interval (both active video and horizontal blanking portions of the line). FORMAT 0 (Address 0Bh) The LMH0031 may be set to process a single video format by writing the appropriate data into the FORMAT 0 register. The Format Set[4:0] bits confine the LMH0031 to recognize and process only one of the fourteen specified type of SD or HD formats defined by a particular SMPTE specification. The Format Set[4:0] bits may not be used to confine device operation to a range of standards. The available formats and codes are detailed in Table 4. Generally speaking, the Format Set[4:0] codes indicate or group the formats as follows: Format Set[4] is set for the HD data formats, reset for SD data formats. Format Set[3] is set for PAL data formats (with the exception of the SMPTE 274M 24-frame progressive format), reset for NTSC data formats. Format Set[2:0] further sub-divide the standards as given in the table. 21 www.national.com LMH0031 Device Operation LMH0031 Device Operation (Continued) TABLE 4. Video Raster Format Parameters Format Code [4,3,2,1,0] Format Spec. Frame Rate Lines Active Lines Samples Active Samples 00001 SDTV, 54 RP 174 60I 525 507/487* 3432 2880 00010 SDTV, 36 SMPTE 267 60I 525 507/487* 2288 1920 00011 SDTV, 27 SMPTE 125 60I 525 507/487* 1716 1440 01001 SDTV, 54 ITU-R BT 601.5 50I 625 577 3456 2880 01010 SDTV, 36 ITU-R BT 601.5 50I 625 577 2304 1920 01011 SDTV, 27 ITU-R BT 601.5 50I 625 577 1728 1440 10001 HDTV, 74.25 SMPTE 260 30I 1125 1035 2200 1920 10010 HDTV, 74.25 SMPTE 274 30I 1125 1080 2200 1920 10011 HDTV, 74.25 SMPTE 274 30P 1125 1080 2200 1920 11001 HDTV, 74.25 SMPTE 274 25I 1125 1080 2640 1920 11010 HDTV, 74.25 SMPTE 274 25P 1125 1080 2640 1920 11100 HDTV, 74.25 SMPTE 295 25I 1250 1080 2376 1920 11101 HDTV, 74.25 SMPTE 274 24P 1125 1080 2750 1920 10100 HDTV, 74.25 SMPTE 296 (1, 2) 60P 750 720 1650 1280 The HD Only bit when set to a logic-1 locks the LMH0031 into the high definition data range and frequency. In systems designed to handle only high definition signals, enabling HD Only reduces the time required for the LMH0031 to establish frequency lock and determine the HD format being processed. The SD Only bit when set to a logic-1 locks the LMH0031 into the standard definition data ranges and frequencies. In systems designed to handle only standard definition signals, enabling SD Only reduces the time required for the LMH0031 to establish frequency lock and determine the format being processed. When SD Only and HD Only are set to logic-0, the device operates in SD/HD mode. The Framing Mode bit in the Format 0 register and Framing Enable in the Video Info 0 register combine with Framing Enable to control the manner in which the LMH0031 aligns framing. When Framing Mode and Framing Enable are both reset, the LMH0031 aligns on the first valid TRS character. If another TRS occurs that is not on a word boundary, the NSP bit is set until the next TRS that is on a word boundary occurs. When Framing Mode is set to a logic-1, the LMH0031 operates similarly to the CLC011 when NSP is tied to FE. An alternative configuration that operates identically can be achieved with the LMH0031 by mapping NSP as an output and Framing Enable as an input on the Multifunction I/O bus and externally connecting them. In this case Framing Mode should be reset to a logic-0. When Framing Mode is reset and Framing Enable is set, the LMH0031 realigns on every valid TRS. The initial state of Framing Mode is set following a reset or at power-on. of the many possible video data standards that the LMH0031 can process is being received. These format codes follow the same arrangement as for the Format Set[4:0] bits. These formats and codes are given in Table 4. Bit Format[4] when set indicates that HD data is being processed. When reset, SD data is indicated. Format[3] when set indicates that PAL data is being processed. When reset NTSC data is being processed. Format[2:0] correspond with one of the sub-standards given in the table. Note that the LMH0031 does not distinguish or log the data rate differences between HD data at 74.25Mhz and 74.25MHz/1.001. The H, V, and F bits correspond to input TRS data bits 6, 7 and 8, respectively. The meaning and function of this data is the same for both standard definition (SMPTE 125M) and high definition (SMPTE 292M luminance and colour difference) video data. Polarity is logic-1 equals HIGH-true. These bits are registered for the duration of the applicable field. TEST 0 REGISTER (Address 0Dh) The Test Pattern Select bits determine which test pattern is output when the Test Pattern Generator (TPG) mode or the Built-in Self-Test (BIST) mode is enabled. Table 5 gives the codes corresponding to the various test patterns. All HD colour bar test patterns are inherently BIST data. BIST test patterns for SD are: NTSC, 27MHz, 4x3 Colour Bars and PAL, 27MHz, 4x3 PLL Pathological. The TPG Enable bit when set to a logic-1 enables the Test Pattern Generator function and built-in self-test (BIST). The Pass/Fail bit indicates the result of the built-in self-test. This bit is a logic-1 for a pass condition. FORMAT 1 (Address 0Ch) The LMH0031 automatically determines the format of the incoming serial data. The result of this operation is stored in the FORMAT 1 register. The Format[4:0] bits identify which www.national.com 22 LMH0031 Device Operation (Continued) TABLE 5. Test Pattern Selection Codes Test Pattern Select Word Bits > Video Raster Standard Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 1=HD 1=Progressive 0=Interlaced 00=Black 01=PLL Path. 0=SD 1=PAL 0=NTSC 10=EQ Path. 11=Colour Bars 1125 Line, 74.25 MHz, 30 Frame Interlaced Component (SMPTE 260M) Ref. Black 1 0 0 0 0 0 PLL Path. 1 0 0 0 0 1 EQ Path. 1 0 0 0 1 0 Colour Bars 1 0 0 0 1 1 0 0 1 0 0 1125 Line, 74.25 MHz, 30 Frame Interlaced Component (SMPTE 274M) Ref. Black 1 PLL Path. 1 0 0 1 0 1 EQ Path. 1 0 0 1 1 0 Colour Bars 1 0 0 1 1 1 1125 Line, 74.25 MHz, 25 Frame Interlaced Component (SMPTE 274M) Ref. Black 1 0 1 0 0 0 PLL Path. 1 0 1 0 0 1 EQ Path. 1 0 1 0 1 0 Colour Bars 1 0 1 0 1 1 1125 Line, 74.25 MHz, 25 Frame Interlaced Component (SMPTE 295M) Ref. Black 1 0 1 1 0 0 PLL Path. 1 0 1 1 0 1 EQ Path. 1 0 1 1 1 0 Colour Bars 1 0 1 1 1 1 1125 Line, 74.25 MHz, 30 Frame Progressive Component (SMPTE 274M) Ref. Black 1 1 0 0 0 0 PLL Path. 1 1 0 0 0 1 EQ Path. 1 1 0 0 1 0 Colour Bars 1 1 0 0 1 1 1125 Line, 74.25 MHz, 25 Frame Progressive Component (SMPTE 274M) Ref. Black 1 1 0 1 0 0 PLL Path. 1 1 0 1 0 1 EQ Path. 1 1 0 1 1 0 Colour Bars 1 1 0 1 1 1 1125 Line, 74.25 MHz, 24 Frame Progressive Component (SMPTE 274M) Ref. Black 1 1 1 0 0 0 PLL Path. 1 1 1 0 0 1 EQ Path. 1 1 1 0 1 0 Colour Bars 1 1 1 0 1 1 750 Line, 74.25 MHz, 60 Frame Progressive Component (SMPTE 296M) Ref. Black 1 1 1 1 0 0 PLL Path. 1 1 1 1 0 1 EQ Path. 1 1 1 1 1 0 Colour Bars 1 1 1 1 1 1 23 www.national.com LMH0031 Device Operation (Continued) TABLE 5. Test Pattern Selection Codes (Continued) Test Pattern Select Word Bits > Bit 5 Bit 4 Bit 3 Bit 2 Bit 1 Bit 0 0 0 0 0 0 525 Line, 30 Frame, 27 MHz, NTSC 4x3 (SMPTE 125M) Ref. Black 0 PLL Path. 0 0 0 0 0 1 EQ Path. 0 0 0 0 1 0 Colour Bars (SD BIST) 0 0 0 0 1 1 625 Line, 25 Frame, 27 MHz, PAL 4x3 (ITU-T BT.601) Ref. Black 0 1 0 0 0 0 PLL Path. (SD BIST) 0 1 0 0 0 1 EQ Path. 0 1 0 0 1 0 Colour Bars 0 1 0 0 1 1 0 0 1 0 0 525 Line, 30 Frame, 36 MHz, NTSC 16x9 (SMPTE 125M) Ref. Black 0 PLL Path. 0 0 0 1 0 1 EQ Path. 0 0 0 1 1 0 Colour Bars 0 0 0 1 1 1 625 Line, 25 Frame, 36 MHz, PAL 16x9 (ITU-T BT.601) Ref. Black 0 1 0 1 0 0 PLL Path. 0 1 0 1 0 1 EQ Path. 0 1 0 1 1 0 Colour Bars 0 1 0 1 1 1 0 0 1 0 0 0 525 Line, 30 Frame, 54 MHz (NTSC) Ref. Black PLL Path. 0 0 1 0 0 1 EQ Path. 0 0 1 0 1 0 Colour Bars 0 0 1 0 1 1 Ref. Black 0 1 1 0 0 0 PLL Path. 0 1 1 0 0 1 EQ Path. 0 1 1 0 1 0 Colour Bars 0 1 1 0 1 1 625 Line, 25 Frame, 54 MHz (PAL) Note: BIST test patterns for SD are: NTSC 4x3 Colour Bars and PAL 4x3 PLL Pathological. VIDEO INFO 0 REGISTER (Address 0Eh) Re-synchronization of the parallel video output data with the parallel rate clock is controlled by the functions Framing Enable, Framing Mode and NSP. For operating details about these control bits, refer to the preceeding section about Format Registers 0 and 1 and the Format Mode bit. Framing Enable may be assigned as an input on the multifunction I/O port. The NSP (New Sync Position) bit indicates that a new or out-of-place TRS character has been detected in the input data. This bit is set to a logic-1 and remains set for at least one horizontal line period or unless re-activated by a subsequent new or out-of-place TRS. It is reset by an EAV TRS character. The EAV (end of active video) and SAV (start of active video) bits track the occurrence of the corresponding TRS characters. The Lock Detect is a logic-1 when the loop is locked and the CDR has acquired a phase of the incoming serial data. This www.national.com bit may be programmed as an output on the multi-function I/O bus. This bit is mapped to I/O port bit 4 in the default condition. The VPG Filter Enable bit when set enables operation of the Video Pattern Generator filter. Operation of this filter causes the insertion of transition codes in the chroma and luma data of colour bar test patterns where these patterns change from one bar to the next. This filter reduces the magnitude of out-of-band frequency products which are produced by abrupt transitions in the chroma and luma data when fed to D-to-A converters and picture monitors. The LMH0031 incorporates circuitry that implements a method for handling data that has been subjected to LSB dithering. Data from the de-scrambler is routed for dedithering. Control of this circuitry is via the De-Dither Enable bit in the VIDEO INFO 0 control register. Recovery of data that has been dithered during the vertical blanking interval can be selectively enabled by use of the V De-Dither Enable bit in the VIDEO INFO 0 control register. The initial condition of De-Dither Enable and V De-Dither Enable is OFF. 24 LMH0031 as a reference. The default state of this bit at power-on is enabled. In general, this function and bit should not be disabled. The INT_OSC EN bit enables the internal crystal oscillator amplifier. By default this bit is a logic-0 and is therefore inactive at power-on. The device expects an external 27MHz reference reference clock source to be connected to the XTALi/Ext Clk pin and activated at power-on. (Continued) VIDEO CONTROL 0 (register address 55h) The EXTERNAL VCLK bit is a special application function which enables use of an external VCXO as a substitute for the internally generated VCLK. Additional circuitry is enabled within the LMH0031 which provides phase-frequency detection and control voltage output for the VCXO. An external loop filter and voltage amplifier are required to interface the control voltage output to the VCXO frequency control input. When this function is used, the RBB output function is changed from the bias supply output to the control voltage output of the phase-frequency detector. The VCLK output changes function, becoming the input for the VCXO signal. Use of this function and required external support circuitry is explained in the Section Application Information section. The SYNC DETECT ENABLE bit, when set, enables detection of TRS characters. This bit is normally set (ON). I/O PIN 0 THROUGH 7 CONFIGURATION REGISTERS (Addresses 0Fh through 16h) The I/O Pin Configuration Registers are used to map individual bits of the multi-function I/O port to selected bits of the Configuration and Control Registers. Table 6 gives the pin select codes for the Configuration and Control register functions that may be mapped to the port. Pin[n] Select [5] controls whether the port pin is input or output. The port pin will be an input when this bit is set and an output when reset. Input-only functions may not be configured as outputs and vice versa. The remaining five Pin[n] Select [4:0] bits identify the particular Control Register bit to be mapped. The LSB CLIP ENABLE bit, when set, causes the two LSBs of TRS characters to be set to 00b as described in ITU-R BT.601. This function is normally set (ON). Example: Program, via the AD port, I/O port bit 0 as output for the CRC Luma Error bit in the control registers. The NRZI ENABLE bit, when set, enables data to be converted from NRZI to NRZ. This bit is normally set (ON). 1. Set ANC/CTRL to a logic-low. 2. Set RD/WR to a logic-low. 3. Present 00Fh to AD[9:0] as the I/O PIN 0 CONFIG register address. 4. Toggle ACLK. 5. Present 310h to AD[9:0] as the register data, the bit address of the CRC Luma Error bit in the control registers. 6. Toggle ACLK. The DE-SCRAMBLE ENABLE bit, when set, enables descrambling of the incoming data according to requirements of SMPTE 259M or SMPTE 292M. This bit is normally set (ON). CAUTION: The default state of this register is 36h. If any of the normal operating features of the descrambler are turned off, this register’s default data must be restored to resume normal device operation. REFERENCE CLOCK REGISTER (Address 67h) The Reference Clock register controls operation of the CDR reference clock source. The CLKEN bit when reset to a logic-0 enables the oscillator signal to be used by the 25 www.national.com LMH0031 Device Operation LMH0031 Device Operation (Continued) TABLE 6. Control Register Bit, Pin[n] SEL[5:0] Codes for I/O Port Pin Mapping Pin[n] SEL[5:0] Codes [5] [4] [3] [2] [1] [0] HEX I/P or O/P reserved 0 0 0 0 0 0 00 O/P FF Flag Error 0 0 0 0 0 1 01 O/P AP Flag Error 0 0 0 0 1 0 02 O/P ANC Flag Error 0 0 0 0 1 1 03 O/P CRC Error (SD/HD) 0 0 0 1 0 0 04 O/P ANC FIFO 90% FULL 0 0 0 1 1 1 07 O/P SHORT MSG DETECT 0 0 1 0 0 0 08 O/P FULL MSG AVAIL 0 0 1 0 0 1 09 O/P Register Bit Power-On Status I/O Port Bit 5 Addresses 05h and 06h are reserved Addresses 0Ah through 0Ch are reserved SAV 0 0 1 1 0 1 0D O/P EAV 0 0 1 1 1 0 0E O/P NSP 0 0 1 1 1 1 0F O/P CRC Luma Error 0 1 0 0 0 0 10 O/P CRC Chroma Error 0 1 0 0 0 1 11 O/P F 0 1 0 0 1 0 12 O/P I/O Port Bit 0 V 0 1 0 0 1 1 13 O/P I/O Port Bit 1 H 0 1 0 1 0 0 14 O/P I/O Port Bit 2 Format[0] 0 1 0 1 0 1 15 O/P Format[1] 0 1 0 1 1 0 16 O/P Format[2] 0 1 0 1 1 1 17 O/P Format[3] 0 1 1 0 0 0 18 O/P Format[4] 0 1 1 0 0 1 19 O/P FIFO Full 0 1 1 0 1 0 1A O/P FIFO Empty 0 1 1 0 1 1 1B O/P I/O Port Bit 6 Lock Detect 0 1 1 1 0 0 1C O/P I/O Port Bit 4 Pass/Fail 0 1 1 1 0 1 1D O/P FIFO Overrun 0 1 1 1 1 0 1E O/P ANC Chksum Error 0 1 1 1 1 1 1F O/P EDH Force 1 0 0 0 0 0 20 I/P Test Pattern Select[0] 1 0 0 0 0 1 21 I/P Test Pattern Select[1] 1 0 0 0 1 0 22 I/P Test Pattern Select[2] 1 0 0 0 1 1 23 I/P Test Pattern Select[3] 1 0 0 1 0 0 24 I/P Test Pattern Select[4] 1 0 0 1 0 1 25 I/P Test Pattern Select[5] 1 0 0 1 1 0 26 I/P EDH Enable 1 0 0 1 1 1 27 I/P TPG Enable 1 0 1 0 0 0 28 I/P Addresses 29h through 2Bh are reserved VPG Filter Enable 1 0 1 1 0 0 2C I/P De-Dither Enable 1 0 1 1 0 1 2D I/P Framing Enable 1 0 1 1 1 0 2E I/P FIFO Extract Enable 1 0 1 1 1 1 2F I/P www.national.com 26 I/O Port Bit 7 I/O Port Bit 3 (SD/HD) LMH0031 Pin Descriptions Pin Name Description 1 AD9 Ancillary Data Output, Control Data Input 2 AD8 Ancillary Data Output, Control Data Input 3 AD7 Ancillary Data Output, Control Data Input 4 AD6 Ancillary Data Output, Control Data Input 5 AD5 Ancillary Data Output, Control Data Input 6 VSSD Negative Power Supply Input (2.5V supply, Digital Logic) 7 AD4 Ancillary Data Output, Control Data Input 8 AD3 Ancillary Data Output, Control Data Input 9 AD2 Ancillary Data Output, Control Data Input 10 AD1 Ancillary Data Output, Control Data Input 11 AD0 Ancillary Data Output, Control Data Input 12 VDDD Positive Power Supply Input (2.5V supply, Digital Logic) 13 ACLK ancillary/Control Clock Input 14 IO7 Multi-Function I/O Port 15 IO6 Multi-Function I/O Port 16 IO5 Multi-Function I/O Port 17 IO4 Multi-Function I/O Port 18 IO3 Multi-Function I/O Port 19 IO2 Multi-Function I/O Port 20 VSSIO Negative Power Supply Input (3.3V supply, I/O) 21 DV19 Parallel Video Output (HD=Luma) 22 DV18 Parallel Video Output (HD=Luma) 23 DV17 Parallel Video Output (HD=Luma) 24 DV16 Parallel Video Output (HD=Luma) 25 DV15 Parallel Video Output (HD=Luma) 26 VDDIO Positive Power Supply Input (3.3V supply, I/O) 27 DV14 Parallel Video Output (HD=Luma) 28 DV13 Parallel Video Output (HD=Luma) 29 DV12 Parallel Video Output (HD=Luma) 30 DV11 Parallel Video Output (HD=Luma) 31 DV10 Parallel Video Output (HD=Luma) 32 VSSD Negative Power Supply Input (2.5V supply, Digital Logic) 33 VDDD Positive Power Supply Input (2.5V supply, Digital Logic) 34 DV9 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 35 DV8 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 36 DV7 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 37 DV6 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 38 DV5 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 39 VSSD Negative Power Supply Input (2.5V supply, Digital Logic) 40 DV4 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 41 DV3 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 42 DV2 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 43 DV1 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 44 DV0 Parallel Video Output (HD=Chroma, SD=Luma & Chroma) 45 IO1 Multi-Function I/O Port 46 IO0 Multi-Function I/O Port 47 VSSIO Negative Power Supply Input (3.3V supply, I/O) 48 VDDIO Positive Power Supply Input (3.3V supply, I/O) 49 RESET Manual Reset Input (High True) 27 www.national.com LMH0031 Pin Descriptions Pin (Continued) Name Description 50 VCLK Parallel Video Data Clock Output 51 VDDPLL Positive Power Supply Input (2.5V supply, PLL) 52 VSSPLL Negative Power Supply Input (2.5V supply, PLL) 53 RREF Current Reference Resistor 54 RBB SDI Bias Supply Resistor 55 VSSSI Negative Power Supply Input (3.3V supply, Serial Input) 56 SDI Serial Data Complement Input 57 SDI Serial Data True Input 58 VDDSI Positive Power Supply Input (3.3V supply, Serial Input) 59 VSSIO Negative Power Supply Input (3.3V supply, I/O) 60 XTALi/EXT CLK Crystal or External 27MHz Clock Input 61 XTALo Crystal (Oscillator Output) 62 VDDD Positive Power Supply Input (2.5V supply, Digital Logic) 63 ANC/CTRL ancillary/Control Data Port Function Control Input 64 RD/WR ancillary/Control Data Port Read/Write Control Input Note: All LVCMOS inputs have internal pull-down devices except VCLK and ACLK. viding short paths for image currents which reduces signal distortion. The planes should be pulled back from all transmission lines and component mounting pads a distance equal to the width of the widest transmission line or the thickness of the dielectric separating the transmission line from the internal power or ground plane(s) whichever is greater. Doing so minimizes effects on transmission line impedances and reduces unwanted parasitic capacitances at component mounting pads. In especially noisy power supply environments, such as is often the case when using switching power supplies, separate filtering may be used at the LMH0031’s PLL and serial input power pins. The LMH0031 was designed for this situation. The I/O, digital section, PLL and serial input power supply feeds are independent (see pinout description table and pinout drawing for details). Supply filtering may take the form of L-section or pi-section, L-C filters in series with these VDD inputs. Such filters are available in a single package from several manufacturers. Device power supplies must be either sequenced as described in Section POWER SUPPLIES, POWER-ON-RESET AND RESET INPUT and ideally should be applied simultaneously as from a common source. Application Information A typical application circuit for the LMH0031 is shown in the Application Circuit diagram. This circuit demonstrates the capabilities of the LMH0031 and allows its evaluation in a native configuration. An assembled demonstration board is available, part number SD131EVK. The board may be ordered through any of National’s sales offices. Complete circuit board layouts and schematics for the SD131EVK are available on National’s WEB site. For latest availability information, please see: www.national.com/appinfo/interface. PCB LAYOUT AND POWER SYSTEM BYPASS RECOMMENDATIONS Circuit board layout and stack-up for the LMH0031 should be designed to provide noise-free power to the device. Good layout practice also will separate high frequency or highlevel inputs and outputs from low-level inputs to minimize unwanted stray noise pickup, feedback and interference. Power system performance may be greatly improved by using thin dielectrics (4 to 10 mils) for power/ground sandwiches. This increases the intrinsic capacitance of the PCB power system which improves power supply filtering, especially at high frequencies, and makes the value and placement of external bypass capacitors less critical. External bypass capacitors should include both RF ceramic and tantalum electrolytic types. RF capacitors may use values in the range 0.01 µF to 0.1 µF. Tantalum capacitors may be in the range 2.2 µF to 10 µF. Voltage rating for tantalum capacitors should be at least 5X the power supply voltage being used. It is recommended practice to use two vias at each power pin of the LMH0031 as well as all RF bypass capacitor terminals. Dual vias reduce the interconnect inductance by up to half, thereby extending the effective frequency range of the bypass components. The outer layers of the PCB may be flooded with additional VSS (ground) plane. These planes will improve shielding and isolation as well as increase the intrinsic capacitance of the power supply plane system. Naturally, to be effective, these planes must be tied to the VSS power supply plane at frequent intervals with vias. Frequent via placement also improves signal integrity on signal transmission lines by prowww.national.com MAINTAINING OUTPUT DATA INTEGRITY The way in which the TRS and other video data characters are specified and are therefore output in parallel form can result in the simultaneous switching of many of the LMH0031’s CMOS outputs. Such switching can lead to the production of output high level droop or low level ground bounce. Given in the specifications, VOLP is the peak output LOW voltage or ground bounce and VOHV is the lowest output HIGH voltage or output droop that may occur under dynamic simultaneous output switching conditions. VOHV and VOLP are measured with respect to reference ground. Careful attention to PCB layout, power pin connections to the power planes and timing of the output data clocking can reduce these effects. Consideration must also be given to the timing allocated to external circuits which sample the outputs. The effects of simultaneous output switching on output levels may be minimized by adopting good PCB layout and data 28 HD format. (The user should consult Table 4 for guidance on the format groups similar to the non-supported one to be processed). Since most non-supported formats are in the HD group, the LMH0031 should be configured to operate in HD-ONLY mode by setting bit-5 of the FORMAT 0 register (address 0Bh). Also, the device should be further configured by loading the FORMAT SET[4:0] bits of this register with the general HD sub-format code. In addition, since control data is being written to the port, AD[9:8] must be driven as 11b. The complete data word for this general HD sub-format code with HD-ONLY bit set is 33Fh. Since this format differs from those in the table, the EAV/SAV indicators are disabled. Without these indicators, line numbering and CRC processing are disabled and ANC data extraction will not function. Output video chroma and luma data will be word-aligned. Post-processing of the parallel data output from the LMH0031 will be needed to implement CRC checking or line number tracking. (Continued) output timing practices, especially critical at HD data rates. The power pins feeding the I/O should have low inductance connections to the power and ground planes. It is recommended that these connections use at least two vias per power or ground pin. Short interconnecting traces consistent with good layout practices and soldering rules must be used. Sampling or clocking of data by external devices should be so timed as to take maximum advantage of the steady-state portion of the parallel output data interval. The LMH0031 is designed so that video data will be stable at the positivegoing transition of VCLK. Data should not be sampled close to the data transition intervals associated with the negativegoing clock edge. The specified propagation delay and clock to data timing parameters must be observed. When data is being sampled from the video data port together with the ANC port and/or I/O port, it is recommended that the sampling clocks be synchronized with the video clock, VCLK, to minimize possible effects from ground bounce or output droop on sampled signal levels. USING EXTERNAL VCXO FOR VCLK The EXTERNAL VCLK bit of VIDEO CONTROL 0 (register address 55h) is a special application function which enables use of an external VCXO as a substitute for the internally generated VCLK. Additional circuitry is enabled within the LMH0031 which provides phase-frequency detection and control voltage output for the VCXO. An external loop filter and voltage amplifier are required to interface the control voltage output to the VCXO frequency control input. When this function is used, the RBB output function is changed from the bias supply output to the control voltage output of the phase-frequency detector. The VCLK output changes function, becoming the input for the VCXO signal. Figure 7 shows an example using dual VCXOs for VCLK to handle both standard and high definition video. PROCESSING NON-SUPPORTED RASTER FORMATS The number and type of HD raster formats has proliferated since the LMH0031 was designed. Though not specifically capable of fully or automatically processing these new formats, the LMH0031 may still be capable of deserializing them. The user is encouraged to experiment with processing these formats, keeping in mind that the LMH0031 has not been tested to handle formats other than those detailed in Table 4. Therefore, the results from attempts to process non-supported formats is not guaranteed. The following guidelines concerning device setup are provided to aid the user in configuring the LMH0031 to attempt limited processing of these other raster formats. In general, the device is configured to defeat its automatic format detection function and to limit operation to a general 29 www.national.com LMH0031 Application Information LMH0031 Application Information (Continued) 20179614 FIGURE 7. Using Dual VCXOs for VCLK Example The control voltage output from RBB is externally filtered by the loop filter consisting of a 22.1kΩ resistor in series with a 10nF capacitor, combined in parallel with a 100pF capacitor. This gives a loop bandwidth of 1.5kHz. Since the control voltage is limited to around 2.1V, it requires a level shifter to get the entire pull range on the VCXO. National’s LMC7101 is recommended with 100kΩ and 182kΩ resistors as shown in Figure 7 to provide a gain of 1.55, sufficient to drive a 3.3V VCXO. Recommended VCXOs from SaRonix (141 Jefferson Drive, Menlo Park, CA 94025, USA) include the ST1308AAB-74.25 for high definition and the ST1307BAB-27.00 for standard definition. Dual VCXOs require some supporting logic to select the appropriate VCXO. This requires the use of Format[4] (SD/HD) and Lock Detect, which are mapped at power-on to I/O Port Bit 3 and I/O Port Bit 4, respectively. www.national.com These two signals pass through an AND gate (Fairchild Semiconductor’s NC7SZ08 or similar). Its output is high when both Lock Detect and Format[4] are high, which indicates a valid high-definition signal is present. The VCXOs are buffered to control the transition times and to allow easy selection. The output of the AND gate is used to control the Output Enable (OE) function of the buffers. The 74.25MHz VCXO is buffered with the NC7SZ126 with the AND gate output connected to the OE pin of the NC7SZ126, and the 27.00MHz VCXO is buffered with the NC7SZ125 with the AND gate output connected to the OE pin of the NC7SZ125. This circuit uses the 27.00MHz VCXO as default and enables the 74.25MHz VCXO when a valid high-definition signal is present. The outputs from the buffers are daisychained together and sent to the LMH0031’s VCLK in addition to other devices, such as the LMH0030 serializer. 30 inches (millimeters) unless otherwise noted 64-Pin TQPF Order Number LMH0031VS NS Package Number VEC-64A National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications. For the most current product information visit us at www.national.com. LIFE SUPPORT POLICY NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein: 1. Life support devices or systems are devices or systems which, (a) are intended for surgical implant into the body, or (b) support or sustain life, and whose failure to perform when properly used in accordance with instructions for use provided in the labeling, can be reasonably expected to result in a significant injury to the user. 2. A critical component is any component of a life support device or system whose failure to perform can be reasonably expected to cause the failure of the life support device or system, or to affect its safety or effectiveness. BANNED SUBSTANCE COMPLIANCE National Semiconductor manufactures products and uses packing materials that meet the provisions of the Customer Products Stewardship Specification (CSP-9-111C2) and the Banned Substances and Materials of Interest Specification (CSP-9-111S2) and contain no ‘‘Banned Substances’’ as defined in CSP-9-111S2. Leadfree products are RoHS compliant. National Semiconductor Americas Customer Support Center Email: [email protected] Tel: 1-800-272-9959 www.national.com National Semiconductor Europe Customer Support Center Fax: +49 (0) 180-530 85 86 Email: [email protected] Deutsch Tel: +49 (0) 69 9508 6208 English Tel: +44 (0) 870 24 0 2171 Français Tel: +33 (0) 1 41 91 8790 National Semiconductor Asia Pacific Customer Support Center Email: [email protected] National Semiconductor Japan Customer Support Center Fax: 81-3-5639-7507 Email: [email protected] Tel: 81-3-5639-7560 LMH0031 SMPTE 292M/259M Digital Video Deserializer / Descrambler with Video and Ancillary Data FIFOs Physical Dimensions