WM8196 w (8 + 8) Bit Output 16-bit CIS/CCD AFE/Digitiser DESCRIPTION FEATURES The WM8196 is a 16-bit analogue front end/digitiser IC which processes and digitises the analogue output signals from CCD sensors or Contact Image Sensors (CIS) at pixel sample rates of up to 12MSPS. • • • 16-bit ADC 12MSPS conversion rate Low power – 320mW typical • • • 5V single supply or 5V/3.3V dual supply operation Single or 3 channel operation Correlated double sampling • • • Programmable gain (8-bit resolution) Programmable offset adjust (8-bit resolution) Programmable clamp voltage • • • 8 or 4-bit wide multiplexed data output formats Internally generated voltage references 28-lead SSOP package • Serial control interface The device includes three analogue signal processing channels each of which contains Reset Level Clamping, Correlated Double Sampling and Programmable Gain and Offset adjust functions. Three multiplexers allow single channel processing. The output from each of these channels is time multiplexed into a single high-speed 16-bit Analogue to Digital Converter. The digital output data is available in 8 or 4-bit wide multiplexed format. An internal 4-bit DAC is supplied for internal reference level generation. This may be used during CDS to reference CIS signals or during Reset Level Clamping to clamp CCD signals. An external reference level may also be supplied. ADC references are generated internally, ensuring optimum performance from the device. APPLICATIONS Using an analogue supply voltage of 5V and a digital interface supply of either 5V or 3.3V, the WM8196 typically only consumes 300mW when operating from a single 5V supply. • • Flatbed and sheetfeed scanners USB compatible scanners • • Multi-function peripherals High-performance CCD sensor interface BLOCK DIAGRAM VRLC/VBIAS VSMP MCLK DVDD1 DVDD2 AVDD VRT VRX VRB w CL RS VS R G RINP B RLC M U X RLC VREF/BIAS M U X OEB G M U X + OFFSET DAC CDS OFFSET DAC + I/P SIGNAL POLARITY ADJUST PGA 8 + 8 PGA 8 CDS RLC RLC DAC OFFSET DAC + R 8 BINP 8 CDS B GINP WM8196 TIMING CONTROL + AGND2 CONFIGURABLE SERIAL CONTROL INTERFACE SEN SCK SDI RLC/ACYC + I/P SIGNAL POLARITY ADJUST 4 AGND1 DATA I/O PORT 16BIT ADC I/P SIGNAL POLARITY ADJUST PGA 8 M U X OP[0] OP[1] OP[2] OP[3] OP[4] OP[5] OP[6] OP[7]/SDO DGND WOLFSON MICROELECTRONICS plc Production Data, October 2008, Rev 4.6 To receive regular email updates, sign up at http://www.wolfsonmicro.com/enews/ Copyright ©2008 Wolfson Microelectronics plc WM8196 Production Data TABLE OF CONTENTS DESCRIPTION .......................................................................................................1 FEATURES.............................................................................................................1 APPLICATIONS .....................................................................................................1 BLOCK DIAGRAM .................................................................................................1 TABLE OF CONTENTS .........................................................................................2 PIN CONFIGURATION...........................................................................................3 ORDERING INFORMATION ..................................................................................3 PIN DESCRIPTION ................................................................................................4 ABSOLUTE MAXIMUM RATINGS.........................................................................5 RECOMMENDED OPERATING CONDITIONS .....................................................5 THERMAL PERFORMANCE .................................................................................5 ELECTRICAL CHARACTERISTICS ......................................................................6 INPUT VIDEO SAMPLING ............................................................................................. 8 OUTPUT DATA TIMING ................................................................................................ 8 SERIAL INTERFACE ................................................................................................... 10 INTERNAL POWER ON RESET CIRCUIT ..........................................................11 DEVICE DESCRIPTION.......................................................................................13 INTRODUCTION.......................................................................................................... 13 INPUT SAMPLING ....................................................................................................... 13 RESET LEVEL CLAMPING (RLC) ............................................................................... 13 CDS/NON-CDS PROCESSING ................................................................................... 14 OFFSET ADJUST AND PROGRAMMABLE GAIN....................................................... 15 ADC INPUT BLACK LEVEL ADJUST .......................................................................... 16 OVERALL SIGNAL FLOW SUMMARY ........................................................................ 16 CALCULATING OUTPUT FOR ANY GIVEN INPUT .................................................... 16 OUTPUT FORMATS .................................................................................................... 17 CONTROL INTERFACE .............................................................................................. 18 TIMING REQUIREMENTS ........................................................................................... 19 PROGRAMMABLE VSMP DETECT CIRCUIT ............................................................. 19 REFERENCES............................................................................................................. 20 POWER SUPPLY ........................................................................................................ 20 POWER MANAGEMENT ............................................................................................. 20 LINE-BY-LINE OPERATION ........................................................................................ 21 OPERATING MODES .................................................................................................. 22 OPERATING MODE TIMING DIAGRAMS ................................................................... 23 DEVICE CONFIGURATION .................................................................................26 REGISTER MAP .......................................................................................................... 26 REGISTER MAP DESCRIPTION ................................................................................. 27 APPLICATIONS INFORMATION .........................................................................30 RECOMMENDED EXTERNAL COMPONENTS........................................................... 30 RECOMMENDED EXTERNAL COMPONENT VALUE ................................................ 30 PACKAGE DIMENSIONS ....................................................................................31 IMPORTANT NOTICE ..........................................................................................32 ADDRESS:................................................................................................................... 32 w PD Rev 4.6 October 2008 2 WM8196 Production Data PIN CONFIGURATION RINP 1 28 GINP AGND2 2 27 BINP DVDD1 3 26 VRLC/VBIAS OEB 4 25 VRX VSMP 5 24 VRT RLC/ACYC 6 23 VRB MCLK 7 22 AGND1 DGND 8 21 AVDD SEN 9 20 OP[7]/SDO DVDD2 10 19 OP[6] SDI 11 18 OP[5] SCK 12 17 OP[4] OP[0] 13 16 OP[3] OP[1] 14 15 OP[2] ORDERING INFORMATION PACKAGE MOISTURE SENSITIVITY LEVELS PEAK SOLDERING TEMPERATURE 0 to 70 C 28-lead SSOP (Pb free) MSL3 260 C 0 to 70oC 28-lead SSOP (Pb free, tape and reel) MSL3 260oC DEVICE TEMPERATURE RANGE WM8196SCDS/V WM8196SCDS/RV o o Note: Reel quantity = 2,000 w PD Rev 4.6 October 2008 3 WM8196 Production Data PIN DESCRIPTION PIN NAME TYPE 1 RINP Analogue input DESCRIPTION 2 AGND2 Supply Analogue ground (0V). 3 DVDD1 Supply Digital supply (5V) for logic and clock generator. This must be operated at the same potential as AVDD. Red channel input video. 4 OEB Digital input Output Hi-Z control, all digital outputs disabled when OEB = 1. 5 VSMP Digital input Video sample synchronisation pulse. 6 RLC/ACYC Digital input RLC (active high) selects reset level clamp on a pixel-by-pixel basis – tie high if used on every pixel. ACYC autocycles between R, G, B inputs. 7 MCLK Digital input Master clock. This clock is applied at N times the input pixel rate (N = 2, 3, 6, 8 or any multiple of 2 thereafter depending on input sample mode). 8 DGND Supply 9 SEN Digital input 10 DVDD2 Supply 11 SDI Digital input Serial data input. 12 SCK Digital input Serial clock. Digital ground (0V). Enables the serial interface when high. Digital supply (5V/3.3V), all digital I/O pins. Digital multiplexed output data bus. ADC output data (d15:d0) is available in two multiplexed formats as shown, under the control of register MUXOP [1:0] See ‘Output Formats’ description in Device Description section for further details. 8+8-bit 4+4+4+4-bit A B d8 d0 A B C D d0 13 OP[0] Digital output 14 OP[1] Digital output d9 d1 15 OP[2] Digital output d10 d2 16 OP[3] Digital output d11 d3 17 OP[4] Digital output d12 d4 d12 d8 d4 18 OP[5] Digital output d13 d5 d13 d9 d5 d1 19 OP[6] Digital output d14 d6 d14 d10 d6 d2 20 OP[7]/SDO Digital output d15 d7 d15 d11 d7 d3 Alternatively, pin OP[7]/SDO may be used to output register read-back data when OEB = 0 and SEN has been pulsed high. See Serial Interface description in Device Description section for further details. 21 AVDD Supply Analogue supply (5V). This must be operated at the same potential as DVDD1. 22 AGND1 Supply Analogue ground (0V). 23 VRB Analogue output Lower reference voltage. This pin must be connected to AGND via a decoupling capacitor. 24 VRT Analogue output Upper reference voltage. This pin must be connected to AGND via a decoupling capacitor. 25 VRX Analogue output Input return bias voltage. This pin must be connected to AGND via a decoupling capacitor. 26 VRLC/VBIAS Analogue I/O 27 BINP Analogue input Blue channel input video. 28 GINP Analogue input Green channel input video. w Selectable analogue output voltage for RLC or single-ended bias reference. This pin would typically be connected to AGND via a decoupling capacitor. VRLC can be externally driven if programmed Hi-Z. PD Rev 4.6 October 2008 4 WM8196 Production Data ABSOLUTE MAXIMUM RATINGS Absolute Maximum Ratings are stress ratings only. Permanent damage to the device may be caused by continuously operating at or beyond these limits. Device functional operating limits and guaranteed performance specifications are given under Electrical Characteristics at the test conditions specified. ESD Sensitive Device. This device is manufactured on a CMOS process. It is therefore generically susceptible to damage from excessive static voltages. Proper ESD precautions must be taken during handling and storage of this device. Wolfson tests its package types according to IPC/JEDEC J-STD-020B for Moisture Sensitivity to determine acceptable storage conditions prior to surface mount assembly. These levels are: MSL1 = unlimited floor life at <30°C / 85% Relative Humidity. Not normally stored in moisture barrier bag. MSL2 = out of bag storage for 1 year at <30°C / 60% Relative Humidity. Supplied in moisture barrier bag. MSL3 = out of bag storage for 168 hours at <30°C / 60% Relative Humidity. Supplied in moisture barrier bag. The Moisture Sensitivity Level for each package type is specified in Ordering Information. CONDITION MIN MAX Analogue supply voltage: AVDD GND - 0.3V Digital supply voltages: DVDD1 − 2 GND - 0.3V GND + 7V Digital ground: DGND GND - 0.3V GND + 0.3V Analogue grounds: AGND1 − 2 GND - 0.3V GND + 0.3V Digital inputs, digital outputs and digital I/O pins GND - 0.3V DVDD2 + 0.3V Analogue inputs (RINP, GINP, BINP) GND - 0.3V AVDD + 0.3V Other pins GND - 0.3V AVDD + 0.3V GND + 7V 0°C Operating temperature range: TA +70°C 30°C max / 85% RH max Storage temperature prior to soldering -65°C Storage temperature after soldering +150°C Notes: 1. GND denotes the voltage of any ground pin. 2. AGND1, AGND2 and DGND pins are intended to be operated at the same potential. Differential voltages between these pins will degrade performance. RECOMMENDED OPERATING CONDITIONS CONDITION Operating temperature range Analogue supply voltage MIN TA 0 TYP MAX UNITS 70 °C AVDD 4.75 5.0 5.25 V DVDD1 4.75 5.0 5.25 V 5V I/O DVDD2 4.75 5.0 5.25 V 3.3V I/O DVDD2 2.97 3.3 3.63 V Digital core supply voltage Digital I/O supply voltage SYMBOL THERMAL PERFORMANCE PARAMETER SYMBOL TEST CONDITIONS MIN TYP MAX UNIT Performance Thermal resistance – junction to case RθJC Thermal resistance – junction to ambient RθJA Tambient = 25°C 23.9 °C/W 67.1 °C/W Notes: 1. Figures given are for package mounted on 4-layer FR4 according to JESD51-5 and JESD51-7. w PD Rev 4.6 October 2008 5 WM8196 Production Data ELECTRICAL CHARACTERISTICS Test Conditions AVDD = DVDD1 = 5.0V, DVDD2 = 3.3V, AGND = DGND = 0V, TA = 25°C, MCLK = 24MHz unless otherwise stated. PARAMETER SYMBOL TEST CONDITIONS MIN TYP MAX UNIT Overall System Specification (including 16-bit ADC, PGA, Offset and CDS functions) Conversion Rate Full-scale input voltage range (see Note 1) Input signal limits (see Note 2) VIN 12 MSPS 0.4 4.08 Vp-p Vp-p 0 AVDD V Full-scale transition error Gain = 0dB; PGA[7:0] = 4B(hex) 20 mV Zero-scale transition error Gain = 0dB; PGA[7:0] = 4B(hex) 20 mV Differential non-linearity DNL 1.25 LSB Integral non-linearity INL 25 LSB Channel to channel gain matching Total output noise Min Gain Max Gain 1 % 4.5 14 LSB rms LSB rms References Upper reference voltage VRT 2.85 V Lower reference voltage VRB 1.35 V Input return bias voltage VRX Diff. reference voltage (VRT-VRB) VRTB 1.4 Output resistance VRT, VRB, VRX 1.65 1.6 V 1.5 V 1 Ω VRLC/Reset-Level Clamp (RLC) RLC switching impedance 50 Ω VRLC short-circuit current 2 mA VRLC output resistance Ω 2 VRLC Hi-Z leakage current VRLC = 0 to AVDD 1 RLCDAC resolution RLCDAC step size, RLCDACRNG = 0 VRLCSTEP RLCDAC step size, RLCDACRNG = 1 VRLCSTEP RLCDAC output voltage at code 0(hex), RLCDACRNG = 0 VRLCBOT RLCDAC output voltage at code 0(hex), RLCDACRNG = 1 VRLCBOT RLCDAC output voltage at code F(hex) RLCDACRNG, = 0 VRLCTOP RLCDAC output voltage at code F(hex), RLCDACRNG = 1 VRLCTOP AVDD=5V AVDD=5V AVDD=5V VRLC deviation μA 4 bits 0.25 V/step 0.17 V/step 0.39 V 0.26 V 4.16 V 2.81 V -50 +50 mV LSB Offset DAC, Monotonicity Guaranteed Resolution 8 bits Differential non-linearity DNL 0.1 0.5 Integral non-linearity INL 0.25 1 Step size Output voltage Code 00(hex) Code FF(hex) LSB 2.04 mV/step -260 +260 mV mV Notes: 1. 2. Full-scale input voltage denotes the maximum amplitude of the input signal at the specified gain. Input signal limits are the limits within which the full-scale input voltage signal must lie. w PD Rev 4.6 October 2008 6 WM8196 Production Data Test Conditions AVDD = DVDD1 = 5.0V, DVDD2 = 3.3V, AGND = DGND = 0V, TA = 25°C, MCLK = 24MHz unless otherwise stated. PARAMETER SYMBOL TEST CONDITIONS MIN TYP MAX UNIT Programmable Gain Amplifier Resolution Gain 8 bits 208 283 − PGA[7 : 0] V/V Max gain, each channel GMAX 7.4 V/V Min gain, each channel GMIN 0.74 V/V 1 % Gain error, each channel Analogue to Digital Converter Resolution 16 Bits Speed 12 MSPS Full-scale input range (2*(VRT-VRB)) 3 V DIGITAL SPECIFICATIONS Digital Inputs 0.8 ∗ DVDD2 High level input voltage VIH Low level input voltage VIL High level input current IIH 1 μA Low level input current IIL 1 μA Input capacitance CI V 0.2 ∗ DVDD2 5 V pF Digital Outputs High level output voltage VOH IOH = 1mA Low level output voltage VOL IOL = 1mA High impedance output current IOZ DVDD2 - 0.5 V 0.5 V 1 μA 0.2 ∗ DVDD2 V Digital IO Pins 0.8 ∗ DVDD2 Applied high level input voltage VIH Applied low level input voltage VIL High level output voltage VOH IOH = 1mA Low level output voltage VOL IOL = 1mA Low level input current IIL High level input current IIH Input capacitance CI High impedance output current IOZ V DVDD2 - 0.5 V 0.5 V 1 μA 1 μA 1 μA 5 pF Supply Currents Total supply current − active (Three channel mode) MCLK = 24MHz Total supply current − active (Single channel mode) LINEBYLINE = 1 MCLK = 24MHz Total analogue supply current − active (Three channel mode) IAVDD Total analogue supply current − active (One channel mode) IAVDD MCLK = 24MHz LINEBYLINE = 1 MCLK = 24MHz Digital core supply current, DVDD1 − active (Note1) MCLK = 24MHz Digital I/O supply current, DVDD2 − active (Note1) MCLK = 24MHz Supply current − full power down mode w 60 mA 45 mA 56 mA 41 mA 3 mA 1 mA 300 μA PD Rev 4.6 October 2008 7 WM8196 Production Data INPUT VIDEO SAMPLING tPER tMCLKH tMCLKL MCLK tVSMPSU tVSMPH VSMP INPUT tVSU tVH tRSU tRH VIDEO Figure 1 Input Video Timing Note: 1. See Page 14 (Programmable VSMP Detect Circuit) for video sampling description. Test Conditions AVDD = DVDD1 = 5.0V, DVDD2 = 3.3V, AGND = DGND = 0V, TA = 25°C, MCLK = 24MHz unless otherwise stated. PARAMETER SYMBOL MCLK period tPER TEST CONDITIONS 41.6 MIN TYP MAX UNITS ns MCLK high period tMCLKH 18.8 ns MCLK low period tMCLKL 18.8 ns VSMP set-up time tVSMPSU 6 ns VSMP hold time tVSMPH 3 ns Video level set-up time tVSU 10 ns Video level hold time tVH 3 ns Reset level set-up time tRSU 10 ns Reset level hold time tRH 3 ns Notes: 1. 2. tVSU and tRSU denote the set-up time required after the input video signal has settled. Parameters are measured at 50% of the rising/falling edge. OUTPUT DATA TIMING MCLK tPD OP[7:0] Figure 2 Output Data Timing w PD Rev 4.6 October 2008 8 WM8196 Production Data OEB tPZE OP[7:0] tPEZ Hi-Z Hi-Z Figure 3 Output Data Enable Timing Test Conditions AVDD = DVDD1 = 5.0V, DVDD2 = 3.3V, AGND = DGND = 0V, TA = 25°C, MCLK = 24MHz unless otherwise stated. SYMBOL TEST CONDITIONS MIN TYP MAX Output propagation delay PARAMETER tPD IOH = 1mA, IOL = 1mA 10 18 30 UNITS ns Output enable time tPZE 20 ns Output disable time tPEZ 15 ns MCLK tACYCSU tACYCH tACYCSU tACYCH RLC/ACYC PGA/OFFSET MUX OUTPUT Figure 4 Auto Cycle Timing Test Conditions AVDD = DVDD1 = 5.0V, DVDD2 = 3.3V, AGND = DGND = 0V, TA = 25°C, MCLK = 24MHz unless otherwise stated. PARAMETER SYMBOL TEST CONDITIONS MIN TYP MAX UNITS Auto Cycle set-up time tACYCSU 6 ns Auto Cycle hold time tACYCH 3 ns w PD Rev 4.6 October 2008 9 WM8196 Production Data SERIAL INTERFACE tSPER tSCKL tSCKH SCK tSSU tSH SDI tSCE tSEW tSEC SEN ADC DATA tSERD tSCRD t SCRDZ MSB SDO ADC DATA LSB REGISTER DATA Figure 5 Serial Interface Timing Test Conditions AVDD = DVDD1 = 5.0V, DVDD2 = 3.3V, AGND = DGND = 0V, TA = 25°C, MCLK = 24MHz unless otherwise stated. PARAMETER SYMBOL TEST CONDITIONS MIN TYP MAX UNITS SCK period tSPER 41.6 ns SCK high tSCKH 18.8 ns SCK low tSCKL 18.8 ns SDI set-up time tSSU 6 ns SDI hold time tSH 6 ns SCK to SEN set-up time tSCE 12 ns SEN to SCK set-up time tSEC 12 ns SEN pulse width tSEW 25 ns SEN low to SDO = Register data tSERD 30 ns SCK low to SDO = Register data tSCRD 30 ns SCK low to SDO = ADC data tSCRDZ 30 ns Note: 1. Parameters are measured at 50% of the rising/falling edge w PD Rev 4.6 October 2008 10 WM8196 Production Data INTERNAL POWER ON RESET CIRCUIT Figure 6 Internal Power On Reset Circuit Schematic The WM8196 includes an internal Power-On-Reset Circuit, as shown in Figure 6, which is used to reset the digital logic into a default state after power up. The POR circuit is powered from AVDD and monitors DVDD1. It asserts PORB low if AVDD or DVDD1 is below a minimum threshold. The power supplies can be brought up in any order but is important that either AVDD is brought up and is stable before DVDD comes up or vice versa as shown in Figure 7 and Figure 8. Figure 7 Typical Power up Sequence where AVDD is Powered before DVDD1 Figure 7 shows a typical power-up sequence where AVDD is powered up first. When AVDD rises above the minimum threshold, Vpora, there is enough voltage for the circuit to guarantee PORB is asserted low and the chip is held in reset. In this condition, all writes to the control interface are ignored. Now AVDD is at full supply level. Next DVDD1 rises to Vpord_on and PORB is released high and all registers are in their default state and writes to the control interface may take place. On power down, where AVDD falls first, PORB is asserted low whenever AVDD drops below the minimum threshold Vpora_off. w PD Rev 4.6 October 2008 11 WM8196 Production Data Figure 8 Typical Power up Sequence where DVDD1 is Powered before AVDD Figure 8 shows a typical power-up sequence where DVDD1 is powered up first. It is assumed that DVDD1 is already up to specified operating voltage. When AVDD goes above the minimum threshold, Vpora, there is enough voltage for the circuit to guarantee PORB is asserted low and the chip is held in reset. In this condition, all writes to the control interface are ignored. When AVDD rises to Vpora_on, PORB is released high and all registers are in their default state and writes to the control interface may take place. On power down, where DVDD1 falls first, PORB is asserted low whenever DVDD1 drops below the minimum threshold Vpord_off. SYMBOL TYP UNIT Vpora 0.6 V Vpora_on 1.2 V Vpora_off 0.6 V Vpord_on 0.7 V Vpord_off 0.6 V Table 1 Typical POR Operation (typical values, not tested) Note: It is recommended that every time power is cycled to the WM8196 a software reset is written to the software register to ensure that the contents of the control registers are at their default values before carrying out any other register writes. w PD Rev 4.6 October 2008 12 WM8196 Production Data DEVICE DESCRIPTION INTRODUCTION A block diagram of the device showing the signal path is presented on Page 1. The WM8196 samples up to three inputs (RINP, GINP and BINP) simultaneously. The device then processes the sampled video signal with respect to the video reset level or an internally/externally generated reference level using either one or three processing channels. Each processing channel consists of an Input Sampling block with optional Reset Level Clamping (RLC) and Correlated Double Sampling (CDS), an 8-bit programmable offset DAC and an 8-bit Programmable Gain Amplifier (PGA). The ADC then converts each resulting analogue signal to a 16-bit digital word. The digital output from the ADC is presented on an 8-bit wide bi-directional bus, with optional 8 or 4-bit multiplexed formats. On-chip control registers determine the configuration of the device, including the offsets and gains applied to each channel. These registers are programmable via a serial interface. INPUT SAMPLING The WM8196 can sample and process one to three inputs through one or three processing channels as follows: Colour Pixel-by-Pixel: The three inputs (RINP, GINP and BINP) are simultaneously sampled for each pixel and a separate channel processes each input. The signals are then multiplexed into the ADC, which converts all three inputs within the pixel period. Monochrome: A single chosen input (RINP, GINP, or BINP) is sampled, processed by the corresponding channel, and converted by the ADC. The choice of input and channel can be changed via the control interface, e.g. on a line-by-line basis if required. Colour Line-by-Line: A single chosen input (RINP, GINP, or BINP) is sampled and multiplexed into the red channel for processing before being converted by the ADC. The input selected can be switched in turn (RINP → GINP → BINP → RINP…) together with the PGA and Offset DAC control registers by pulsing the RLC/ACYC pin. This is known as auto-cycling. Alternatively, other sampling sequences can be generated via the control registers. This mode causes the blue and green channels to be powered down. Refer to the Line-by-Line Operation section for more details. RESET LEVEL CLAMPING (RLC) To ensure that the signal applied to the WM8196 lies within its input range (0V to AVDD) the CCD output signal is usually level shifted by coupling through a capacitor, CIN. The RLC circuit clamps the WM8196 side of this capacitor to a suitable voltage during the CCD reset period. A typical input configuration is shown in Figure 9. An internal clamp pulse, CL, is generated from MCLK and VSMP by the Timing Control Block. When CL is active the voltage on the WM8196 side of CIN, at RINP, is forced to the VRLC/VBIAS voltage (VVRLC ) by closing of switch 1. When the CL pulse turns off switch 1 opens, the voltage at RINP initially remains at VVRLC but any subsequent variation in sensor voltage (from reset to video level) will couple through CIN to RINP. RLC is compatible with both CDS and non-CDS operating modes, as selected by switch 2. Refer to the CDS/non-CDS Processing section. w PD Rev 4.6 October 2008 13 WM8196 Production Data MCLK RLC/ACYC VSMP TIMING CONTROL CL RS FROM CONTROL INTERFACE VS CIN S/H RINP 2 1 + S/H RLC CDS EXTERNAL VRLC TO OFFSET DAC + INPUT SAMPLING BLOCK FOR RED CHANNEL CDS VRLC/ VBIAS 4-BIT RLC DAC FROM CONTROL INTERFACE VRLCEXT Figure 9 Reset Level Clamping and CDS Circuitry If auto-cycling is not required, RLC can be selected by pin RLC/ACYC. Figure 10 illustrates control of RLC for a typical CCD waveform, with CL applied during the reset period. The input signal applied to the RLC/ACYC pin is sampled on the positive edge of MCLK that occurs during each VSMP pulse. The sampled level, high (or low) controls the presence (or absence) of the internal CL pulse on the next reset level. The position of CL can be adjusted by using control bits CDSREF[1:0] (Figure 11). If auto-cycling is required, pin RLC/ACYC is no longer available for this function and control bit RLCINT determines whether clamping is applied. MCLK VSMP ACYC/RLC or RLCINT 1 X X 0 X X 0 Programmable Delay CL (CDSREF = 01) INPUT VIDEO RGB RGB RLC on this Pixel RGB No RLC on this Pixel Figure 10 Relationship of RLC Pin, MCLK and VSMP to Internal Clamp Pulse, CL The VRLC/VBIAS pin can be driven internally by a 4-bit DAC (RLCDAC) by writing to control bits RLCV[3:0]. The RLCDAC range and step size may be increased by writing to control bit RLCDACRNG. Alternatively, the VRLC/VBIAS pin can be driven externally by writing to control bit VRLCEXT to disable the RLCDAC and then applying a d.c. voltage to the pin. CDS/NON-CDS PROCESSING For CCD type input signals, the signal may be processed using CDS, which will remove pixel-by-pixel common mode noise. For CDS operation, the video level is processed with respect to the video reset level, regardless of whether RLC has been performed. To sample using CDS, control bit CDS must be set to 1 (default), this sets switch 2 into the position shown in Figure 9 and causes the signal reference to come from the video reset level. The time at which the reset level is sampled, by clock Rs/CL, is adjustable by programming control bits CDSREF[1:0], as shown in Figure 11. w PD Rev 4.6 October 2008 14 WM8196 Production Data MCLK VSMP VS RS/CL (CDSREF = 00) RS/CL (CDSREF = 01) RS/CL (CDSREF = 10) RS/CL (CDSREF = 11) Figure 11 Reset Sample and Clamp Timing For CIS type sensor signals, non-CDS processing is used. In this case, the video level is processed with respect to the voltage on pin VRLC/VBIAS, generated internally or externally as described above. The VRLC/VBIAS pin is sampled by Rs at the same time as Vs samples the video level in this mode; non-CDS processing is achieved by setting switch 2 in the lower position, CDS = 0. OFFSET ADJUST AND PROGRAMMABLE GAIN The output from the CDS block is a differential signal, which is added to the output of an 8-bit Offset DAC to compensate for offsets and then amplified by an 8-bit PGA. The gain and offset for each channel are independently programmable by writing to control bits DAC[7:0] and PGA[7:0]. Peak input voltage to match ADC Fullscale Input Range The gain characteristic of the WM8196 PGA is shown in Figure 12. Figure 13 shows the maximum device input voltage that can be gained up to match the ADC full-scale input range (3V). 8 7 PGA Gain (V/V) 6 5 4 3 2 1 0 0 64 128 192 Gain register value (PGA[7:0]) Figure 12 PGA Gain Characteristic 256 4.5 4 3.5 3 2.5 2 1.5 1 0.5 0 0 64 128 192 Gain register value (PGA[7:0]) 256 Figure 13 Peak Input Voltage to Match ADC Full-scale Range In colour line-by-line mode the gain and offset coefficients for each colour can be multiplexed in order (Red → Green → Blue → Red…) by pulsing the ACYC/RLC pin, or controlled via the FME, ACYCNRLC and INTM[1:0] bits. Refer to the Line-by-Line Operation section for more details. w PD Rev 4.6 October 2008 15 WM8196 Production Data ADC INPUT BLACK LEVEL ADJUST The output from the PGA should be offset to match the full-scale range of the ADC (3V). For negative-going input video signals, a black level (zero differential) output from the PGA should be offset to the top of the ADC range by setting register bits PGAFS[1:0]=10. For positive going input signal the black level should be offset to the bottom of the ADC range by setting PGAFS[1:0]=11. Bipolar input video is accommodated by setting PGAFS[1:0]=00 or PGAFS[1:0]=01 (zero differential input voltage gives mid-range ADC output). OVERALL SIGNAL FLOW SUMMARY Figure 14 represents the processing of the video signal through the WM8196. INPUT SAMPLING OFFSET DAC PGA BLOCK BLOCK BLOCK V1 + VIN - V2 ++ X V3 analog x (65535/VFS) +0 if PGAFS[1:0]=11 +65535 if PGAFS[1:0]=10 +32768 if PGAFS[1:0]=0x CDS = 1 D1 D2 OP[7:0] digital D2 = D1 if INVOP = 0 D2 = 65535-D1 if INVOP = 1 VRESET PGA gain A = 208/(283-PGA[7:0]) CDS = 0 VVRLC Offset DAC 260mV*(DAC[7:0]-127.5)/127.5 RLCEXT=0 RLCEXT=1 OUTPUT INVERT BLOCK ADC BLOCK See parametrics for DAC voltages. RLC DAC VIN is RINP or GINP or BINP VRESET is VIN sampled during reset clamp VRLC is voltage applied to VRLC pin CDS, RLCEXT,RLCV[3:0], DAC[7:0], PGA[7:0], PGAFS[1:0] and INVOP are set by programming internal control registers. CDS=1 for CDS, 0 for non-CDS Figure 14 Overall Signal Flow The INPUT SAMPLING BLOCK produces an effective input voltage V1. For CDS, this is the difference between the input video level VIN and the input reset level VRESET. For non-CDS this is the difference between the input video level VIN and the voltage on the VRLC/VBIAS pin, VVRLC, optionally set via the RLC DAC. The OFFSET DAC BLOCK then adds the amount of fine offset adjustment required to move the black level of the input signal towards 0V, producing V2. The PGA BLOCK then amplifies the white level of the input signal to maximise the ADC range, outputting voltage V3. The ADC BLOCK then converts the analogue signal, V3, to a 16-bit unsigned digital output, D1. The digital output is then inverted, if required, through the OUTPUT INVERT BLOCK to produce D2. CALCULATING OUTPUT FOR ANY GIVEN INPUT The following equations describe the processing of the video and reset level signals through the WM8196. The values if V1 V2 and V3 are often calculated in reverse order during device setup. The PGA value is written first to set the input Voltage range, the Offset DAC is then adjusted to compensate for any Black/Reset level offsets and finally the RLC DAC value is set to position the reset level correctly during operation. Note: Refer to WAN0123 for detailed information on device calibration procedures. INPUT SAMPLING BLOCK: INPUT SAMPLING AND REFERENCING If CDS = 1, (i.e. CDS operation) the previously sampled reset level, VRESET, is subtracted from the input video. V1 = VIN - VRESET ................................................................... Eqn. 1 If CDS = 0, (non-CDS operation) the simultaneously sampled voltage on pin VRLC is subtracted instead. V1 = VIN - VVRLC .................................................................... Eqn. 2 If RLCEXT = 1, VVRLC is an externally applied voltage on pin VRLC/VBIAS. w PD Rev 4.6 October 2008 16 WM8196 Production Data If RLCEXT = 0, VVRLC is the output from the internal RLC DAC. VVRLC (VRLCSTEP ∗ RLCV[3:0]) + VRLCBOT ................................. = Eqn. 3 VRLCSTEP is the step size of the RLC DAC and VRLCBOT is the minimum output of the RLC DAC. OFFSET DAC BLOCK: OFFSET (BLACK-LEVEL) ADJUST The resultant signal V1 is added to the Offset DAC output. V2 V1 + {260mV ∗ (DAC[7:0]-127.5) } / 127.5 ..................... = Eqn. 4 PGA NODE: GAIN ADJUST The signal is then multiplied by the PGA gain, V3 V2 ∗ 208/(283- PGA[7:0]) .............................................. = Eqn. 5 ADC BLOCK: ANALOGUE-DIGITAL CONVERSION The analogue signal is then converted to a 16-bit unsigned number, with input range configured by PGAFS[1:0]. D1[15:0] = INT{ (V3 /VFS) ∗ 65535} + 32767 PGAFS[1:0] = 00 or 01 ...... Eqn. 6 D1[15:0] = INT{ (V3 /VFS) ∗ 65535} PGAFS[1:0] = 11 ............... Eqn. 7 D1[15:0] = INT{ (V3 /VFS) ∗ 65535} + 65535 PGAFS[1:0] = 10 ............... Eqn. 8 where the ADC full-scale range, VFS = 3V OUTPUT INVERT BLOCK: POLARITY ADJUST The polarity of the digital output may be inverted by control bit INVOP. D2[15:0] = D1[15:0] (INVOP = 0) ...................... Eqn. 9 D2[15:0] = 65535 – D1[15:0] (INVOP = 1) ...................... Eqn. 10 OUTPUT FORMATS The digital data output from the ADC is available to the user in 8 or 4-bit wide multiplexed formats by setting control bit MUXOP[1:0]. Latency of valid output data with respect to VSMP is programmable by writing to control bits DEL[1:0]. The latency for each mode is shown in the Operating Mode Timing Diagrams section. Figure 15 shows the output data formats for Modes 1 – 2 and 4 – 6. Figure 16 shows the output data formats for Mode 3. Table 2 summarises the output data obtained for each format. MCLK MCLK 8+8-BIT OUTPUT 4+4+4+4-BIT OUTPUT A A B C Figure 15 Output Data Formats (Modes 1 − 2, 4 − 6) w 8+8-BIT OUTPUT B D 4+4+4+4-BIT OUTPUT A B A B A B C D Figure 16 Output Data Formats (Mode 3) PD Rev 4.6 October 2008 17 WM8196 Production Data OUTPUT FORMAT MUXOP[1:0] OUTPUT PINS OUTPUT 8+8-bit multiplexed 00, 01, 10 OP[7:0] A = d15, d14, d13, d12, d11, d10, d9, d8 B = d7, d6, d5, d4, d3, d2, d1,d0 4+4+4+4-bit (nibble) 11 OP[7:4] A = d15, d14, d13, d12 B = d11, d10, d9, d8 C = d7, d6, d5, d4 D = d3, d2, d1, d0 Table 2 Details of Output Data Shown in Figure 15 and Figure 16. CONTROL INTERFACE The internal control registers are programmable via the serial digital control interface. The register contents can be read back via the serial interface on pin OP[7]/SDO. Note: It is recommended that a software reset is carried out after the power-up sequence, before writing to any other register. This ensures that all registers are set to their default values (as shown in Table 6). SERIAL INTERFACE: REGISTER WRITE Figure 17 shows register writing in serial mode. Three pins, SCK, SDI and SEN are used. A six-bit address (a5, 0, a3, a2, a1, a0) is clocked in through SDI, MSB first, followed by an eight-bit data word (b7, b6, b5, b4, b3, b2, b1, b0), also MSB first. Each bit is latched on the rising edge of SCK. When the data has been shifted into the device, a pulse is applied to SEN to transfer the data to the appropriate internal register. Note all valid registers have address bit a4 equal to 0 in write mode. SCK SDI a5 0 a3 a2 a1 a0 b7 b6 Address b5 b4 b3 b2 b1 b0 Data Word SEN Figure 17 Serial Interface Register Write A software reset is carried out by writing to Address “000100” with any value of data, i.e. Data Word = XXXXXXXX. SERIAL INTERFACE: REGISTER READ-BACK Figure 18 shows register read-back in serial mode. Read-back is initiated by writing to the serial bus as described above but with address bit a4 set to 1, followed by an 8-bit dummy data word. Writing address (a5, 1, a3, a2, a1, a0) will cause the contents (d7, d6, d5, d4, d3, d2, d1, d0) of corresponding register (a5, 0, a3, a2, a1, a0) to be output MSB first on pin SDO (on the falling edge of SCK). Note that pin SDO is shared with an output pin, OP[7], therefore OEB should always be held low when register read-back data is expected on this pin. The next word may be read in to SDI while the previous word is still being output on SDO. w PD Rev 4.6 October 2008 18 WM8196 Production Data SCK SDI a5 1 a3 a2 a1 a0 Address x x x x x x x x Data Word SEN SDO/ OP[7] d7 d6 d5 d4 d3 d2 d1 d0 Output Data Word OEB Figure 18 Serial Interface Register Read-back TIMING REQUIREMENTS To use this device a master clock (MCLK) of up to 24MHz and a per-pixel synchronisation clock (VSMP) of up to 12MHz are required. These clocks drive a timing control block, which produces internal signals to control the sampling of the video signal. MCLK to VSMP ratios and maximum sample rates for the various modes are shown in Table 5. PROGRAMMABLE VSMP DETECT CIRCUIT The VSMP input is used to determine the sampling point and frequency of the WM8196. Under normal operation a pulse of 1 MCLK period should be applied to VSMP at the desired sampling frequency (as shown in the Operating Mode Timing Diagrams) and the input sample will be taken on the first rising MCLK edge after VSMP has gone low. However, in certain applications such a signal may not be readily available. The programmable VSMP detect circuit in the WM8196 allows the sampling point to be derived from any signal of the correct frequency, such as a CCD shift register clock, when applied to the VSMP pin. When enabled, by setting the VSMPDET control bit, the circuit detects either a rising or falling edge (determined by POSNNEG control bit) on the VSMP input pin and generates an internal VSMP pulse. This pulse can optionally be delayed by a number of MCLK periods, specified by the VDEL[2:0] bits. Figure 19 shows the internal VSMP pulses that can be generated by this circuit for a typical clock input signal. The internal VSMP pulse is then applied to the timing control block in place of the normal VSMP pulse provided from the input pin. The sampling point then occurs on the first rising MCLK edge after this internal VSMP pulse, as shown in the Operating Mode Timing Diagrams. w PD Rev 4.6 October 2008 19 WM8196 Production Data MCLK INPUT PINS VSMP POSNNEG = 1 (VDEL = 000) INTVSMP VS (VDEL = 001) INTVSMP VS VS (VDEL = 010) INTVSMP VS VS VS (VDEL = 011) INTVSMP VS VS VS (VDEL = 100) INTVSMP VS (VDEL = 101) INTVSMP VS VS VS VS (VDEL = 110) INTVSMP VS VS VS VS (VDEL = 111) INTVSMP VS VS VS VS VS VS POSNNEG = 0 (VDEL = 000) INTVSMP VS (VDEL = 001) INTVSMP VS VS (VDEL = 010) INTVSMP VS VS (VDEL = 011) INTVSMP (VDEL = 111) INTVSMP VS VS VS VS VS VS VS (VDEL = 110) INTVSMP VS VS VS (VDEL = 101) INTVSMP VS VS VS (VDEL = 100) INTVSMP VS VS VS VS VS VS Figure 19 Internal VSMP Pulses Generated by Programmable VSMP Detect Circuit REFERENCES The ADC reference voltages are derived from an internal bandgap reference, and buffered to pins VRT and VRB, where they must be decoupled to ground. Pin VRX is driven by a similar buffer, and also requires decoupling. The output buffer from the RLCDAC also requires decoupling at pin VRLC/VBIAS POWER SUPPLY The WM8196 can run from a 5V single supply or from split 5V (core) and 3.3V (digital interface) supplies. POWER MANAGEMENT Power management for the device is performed via the Control Interface. The device can be powered on or off completely setting by the EN bit and SELPD bit low. Alternatively, when control bit SELPD is high, only blocks selected by further control bits (SELDIS[3:0]) are powered down. This allows the user to optimise power dissipation in certain modes, or to define an intermediate standby mode to allow a quicker recovery into a fully active state. In Line-by-line operation, the green and blue channel PGAs are automatically powered down. All the internal registers maintain their previously programmed value in power down modes and the Control Interface inputs remain active. Table 3 summarises the power down control bit functions. EN SELDPD 0 0 Device completely powers down. 1 0 Device completely powers up. X 1 Blocks with respective SELDIS[3:0] bit high are disabled. Table 3 Power Down Control w PD Rev 4.6 October 2008 20 WM8196 Production Data LINE-BY-LINE OPERATION Certain linear sensors (e.g. Contact Image Sensors) give colour output on a line-by-line basis. i.e. a full line of red pixels followed by a line of green pixels followed by a line of blue pixels. In order to accommodate this type of signal the WM8196 can be set into Monochrome mode, with the input channel switched by writing to control bits CHAN[1:0] between every line. Alternatively, the WM8196 can be placed into colour line-by-line mode by setting the LINEBYLINE control bit. When this bit is set the green and blue processing channels are powered down and the device is forced internally to only operate in MONO mode (because only one colour is sampled at a time) through the red channel. Figure 20 shows the signal path when operating in colour line-by-line mode. VRLC/VBIAS VSMP CL RS VS TIMING CONTROL R G B RINP GINP BINP MCLK RLC INPUT MUX OFFSET MUX CDS OFFSET DAC + R G RLC 8 B PGA 8 PGA MUX + I/P SIGNAL POLARITY ADJUST RLC RLC DAC 16BIT ADC DATA I/O PORT CONFIGURABLE SERIAL/ PARALLEL CONTROL INTERFACE 4 OP[7:0] SEN/STB SCK/RNW SDI/DNA RLC/ACYC NRESET Figure 20 Signal Path When in Line-by-Line Mode In this mode the input multiplexer and (optionally) the PGA/Offset register multiplexers can be autocycled by the application of pulses to the RLC/ACYC input pin by setting the ACYCNRLC register bit. See Figure 4 for detailed timing information. The multiplexers change on the first MCLK rising edge after RLC/ACYC is taken high. A write to the auto-cycle reset register causes these multiplexers to be reset; selecting the RINP pin and the RED offset/gain registers. Alternatively, all three multiplexers can be controlled via the serial interface by writing to register bits INTM[1:0] to select the desired colour. It is also possible for the input multiplexer to be controlled separately from the PGA and Offset multiplexers. Table 4 describes all the multiplexer selection modes that are possible. FME ACYCNRLC 0 0 Internal, no force mux NAME Input mux, offset and gain registers determined by internal register bits INTM1, INTM0. DESCRIPTION 0 1 Auto-cycling, no force mux Input mux, offset and gain registers auto-cycled, RINP → GINP → BINP → RINP… on RLC/ACYC pulse. 1 0 Internal, force mux Input mux selected from internal register bits FM1, FM0; Offset and gain registers selected from internal register bits INTM1, INTM0. 1 1 Auto-cycling, force mux Input mux selected from internal register bits FM1, FM0; Offset and gain registers auto-cycled, RED → GREEN → BLUE → RED… on RLC/ACYC pulse. Table 4 Colour Selection Description in Line-by-Line Mode w PD Rev 4.6 October 2008 21 WM8196 Production Data OPERATING MODES Table 5 summarises the most commonly used modes, the clock waveforms required and the register contents required for CDS and non-CDS operation. MODE DESCRIPTION CDS AVAILABLE MAX SAMPLE RATE SENSOR INTERFACE DESCRIPTION TIMING REQUIREMENTS REGISTER CONTENTS WITH CDS REGISTER CONTENTS WITHOUT CDS 1 Colour Pixel-by-Pixel Yes 4MSPS The 3 input channels are sampled in parallel. The signal is then gain and offset adjusted before being multiplexed into a single data stream and converted by the ADC, giving an output data rate of 12MSPS max. MCLK max = 24MHz MCLK: VSMP ratio is 6:1 SetReg1: 03(hex) SetReg1: 01(hex) 2 Monochrome/ Colour Line-by-Line Yes 4MSPS As mode 1 except: Only one input channel at a time is continuously sampled. MCLK max = 24MHz MCLK: VSMP ratio is 6:1 SetReg1: 07(hex) SetReg1: 05(hex) 3 Fast Monochrome/ Colour Line-by-Line Yes 8MSPS Identical to mode 2 MCLK max = 24MHz MCLK: VSMP ratio is 3:1 Identical to mode 2 plus SetReg3: bits 5:4 must be set to 0(hex) Identical to mode 2 4 Maximum speed Monochrome/ Colour Line-by-Line No 12MSPS Identical to mode 2 MCLK max = 24MHz MCLK: VSMP ratio is 2:1 CDS not possible SetReg1: 45(hex) 5 Slow Colour Pixel-by-Pixel Yes 3MSPS Identical to mode 1 MCLK max = 24MHz MCLK: VSMP ratio is 2n:1, n ≥ 4 Identical to mode 1 Identical to mode 1 6 Slow Monochrome/ Colour Line-by-Line Yes 3MPS Identical to mode 2 MCLK max = 24MHz MCLK: VSMP ratio is 2n:1, n ≥ 4 Identical to mode 2 Identical to mode 2 Table 5 WM8196 Operating Modes Notes: 1. In Monochrome mode, SetReg3 bits 7:6 determine which input is to be sampled. 2. For Colour Line-by-Line, set control bit LINEBYLINE. For input selection, refer to Table 4, Colour Selection Description in Line-by-Line Mode. w PD Rev 4.6 October 2008 22 WM8196 Production Data OPERATING MODE TIMING DIAGRAMS The following diagrams show 8-bit multiplexed output data and MCLK, VSMP and input video requirements for operation of the most commonly used modes as shown in Table 5. The diagrams are identical for both CDS and non-CDS operation. Outputs from RINP, GINP and BINP are shown as R, G and B respectively. X denotes invalid data. 16.5 MCLK PERIODS MCLK VSMP INPUT VIDEO OP[7:0] (DEL = 00) RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB OP[7:0] (DEL = 01) BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB OP[7:0] (DEL = 10) GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB GA GB BA BB RA RB OP[7:0] (DEL = 11) RA RB GA GB BA BB RA RB GA GB BA BB RA RB GB GA BA BB RA RB GA GB BA BB RA RB GA GB BA BB Figure 21 Mode 1 Operation Figure 22 Mode 2 Operation w PD Rev 4.6 October 2008 23 WM8196 Production Data Figure 23 Mode 3 Operation Figure 24 Mode 4 Operation w PD Rev 4.6 October 2008 24 WM8196 Production Data 16.5 MCLK PERIODS MCLK VSMP INPUT VIDEO OP[7:0] (DEL = 00) X X RA RB GA GB BA BB X X RA RB GA GB BA BB X X RA RB GA GB BA BB X X RA RB GA GB OP[7:0] (DEL = 01) BA BB X X RA RB GA GB BA BB X X RA RB GA GB BA BB X X RA RB GA GB BA BB X X RA RB OP[7:0] (DEL = 10) GA GB BA BB X X RA RB GA GB BA BB X X RA RB GA GB BA BB X X RA RB GA GB BA BB X X OP[7:0] (DEL = 11) RA RB GA GB BA BB X X RA RB GA GB BA BB X X RA RB GA GB BA BB X X RA RB GA GB BA BB Figure 25 Mode 5 Operation (MCLK:VSMP Ratio = 8:1) Figure 26 Mode 6 Operation (MCLK:VSMP Ratio = 8:1) w PD Rev 4.6 October 2008 25 WM8196 Production Data DEVICE CONFIGURATION REGISTER MAP The following table describes the location of each control bit used to determine the operation of the WM8196. The register map is programmed by writing the required codes to the appropriate addresses via the serial interface. ADDRESS DESCRIPTION <a5:a0> DEF RW (hex) 000001 Setup Reg 1 000010 000011 000100 BIT b7 b6 b5 b4 b3 b2 b1 b0 0 MODE4 PGAFS[1] PGAFS[0] SELPD MONO CDS EN 03 RW Setup Reg 2 20 RW DEL[1] DEL[0] RLCDACRNG 0 VRLCEXT INVOP MUXOP[1] MUXOP[0] Setup Reg 3 1F RW CHAN[1] CHAN[0] CDSREF [1] CDSREF [0] RLCV[3] RLCV[2] RLCV[1] RLCV[0] Software Reset 00 W FM[1] FM[0] INTM[1] INTM[0] RLCINT FME ACYCNRLC LINEBYLINE 000101 Auto-cycle Reset 00 W 000110 Setup Reg 4 00 RW 000111 Revision Number 41 R 001000 Setup Reg 5 00 RW 0 0 0 POSNNEG VDEL[2] VDEL[1] VDEL[0] VSMPDET 001001 Setup Reg 6 00 RW 0 0 0 0 SELDIS[3] SELDIS[2] SELDIS[1] SELDIS[0] 001010 Reserved 00 RW 0 0 0 0 0 0 0 0 001011 Reserved 00 RW 0 0 0 0 0 0 0 0 001100 Reserved 00 RW 0 0 0 0 0 0 0 0 100000 DAC Value (Red) 80 RW DAC[7] DAC[6] DAC[5] DAC[4] DAC[3] DAC[2] DAC[1] DAC[0] 100001 DAC Value (Green) 80 RW DAC[7] DAC[6] DAC[5] DAC[4] DAC[3] DAC[2] DAC[1] DAC[0] 100010 DAC Value (Blue) 80 RW DAC[7] DAC[6] DAC[5] DAC[4] DAC[3] DAC[2] DAC[1] DAC[0] 100011 DAC Value (RGB) 80 W DAC[7] DAC[6] DAC[5] DAC[4] DAC[3] DAC[2] DAC[1] DAC[0] 101000 PGA Gain (Red) 00 RW PGA[7] PGA[6] PGA[5] PGA[4] PGA[3] PGA[2] PGA[1] PGA[0] 101001 PGA Gain (Green) 00 RW PGA[7] PGA[6] PGA[5] PGA[4] PGA[3] PGA[2] PGA[1] PGA[0] 101010 PGA Gain (Blue) 00 RW PGA[7] PGA[6] PGA[5] PGA[4] PGA[3] PGA[2] PGA[1] PGA[0] 101011 PGA Gain (RGB) 00 W PGA[7] PGA[6] PGA[5] PGA[4] PGA[3] PGA[2] PGA[1] PGA[0] Table 6 Register Map w PD Rev 4.6 October 2008 26 WM8196 Production Data REGISTER MAP DESCRIPTION The following table describes the function of each of the control bits shown in Table 6. REGISTER Setup Register 1 BIT NO BIT NAME(S) DEFAULT DESCRIPTION 0 EN 1 When SELPD = 1 this bit has no effect. When SELPD = 0 this bit controls the global power down: 0 = complete power down, 1 = fully active. 1 CDS 1 Select correlated double sampling mode: 0 = single ended mode, 1 = CDS mode. 2 MONO 0 Mono/colour select: 0 = colour, 1 = monochrome operation. 3 SELPD 0 Selective power down: 0 = no individual control, 1 = individual blocks can be disabled (controlled by SELDIS[3:0]). 5:4 PGAFS[1:0] 00 Offsets PGA output to optimise the ADC range for different polarity sensor output signals. Zero differential PGA input signal gives: 00 = Zero output (use for bipolar video) 01 = Zero output Setup Register 2 10 = Full-scale positive output (use for negative going video) 11 = Full-scale negative output (use for positive going video) 6 MODE4 0 Required when operating in MODE4: 0 = other modes, 1 = MODE4. 7 Reserved 0 Must be set to zero 1:0 MUXOP[1:0] 00 Determines the output data format. 00 = 16-bit parallel 01 = 8-bit multiplexed (8+8 bits) 10 = 8-bit multiplexed mode (8+8 bits) 11 = 4-bit multiplexed mode (4+4+4+4 bits) 2 INVOP 0 Digitally inverts the polarity of output data. 0 = negative going video gives negative going output, 1 = negative-going video gives positive going output data. 3 VRLCEXT 0 When set powers down the RLCDAC, changing its output to Hi-Z, allowing VRLC/VBIAS to be externally driven. 5 RLCDACRNG 1 Sets the output range of the RLCDAC. 0 = RLCDAC ranges from 0 to AVDD (approximately), 1 = RLCDAC ranges from 0 to VRT (approximately). 7:6 DEL[1:0] 00 Sets the output latency in ADC clock periods. 1 ADC clock period = 2 MCLK periods except in Mode 3 where 1 ADC clock period = 3 MCLK periods. 00 = Minimum latency 01 = Delay by one ADC clock period Setup Register 3 3:0 RLCV[3:0] 1111 5:4 CDSREF[1:0] 01 Controls RLCDAC driving VRLC pin to define single ended signal reference voltage or Reset Level Clamp voltage. See Electrical Characteristics section for ranges. CDS mode reset timing adjust. 00 = Advance 1 MCLK period 01 = Normal 7:6 CHAN[1:0] 00 10 = Delay by two ADC clock periods 11 = Delay by three ADC clock periods 10 = Retard 1 MCLK period 11 = Retard 2 MCLK periods Monochrome mode channel select. 00 = Red channel select 01 = Green channel select 10 = Blue channel select 11 = Reserved Software Reset Any write to Software Reset causes all cells to be reset. It is recommended that a software reset be performed after a power-up before any other register writes. Auto-cycle Reset Any write to Auto-cycle Reset causes the auto-cycle counter to reset to RINP. This function is only required when LINEBYLINE = 1. w PD Rev 4.6 October 2008 27 WM8196 REGISTER Setup Register 4 Setup Register 5 Setup Register 6 Production Data BIT NO BIT NAME(S) DEFAULT DESCRIPTION 0 LINEBYLINE 0 Selects line by line operation 0 = normal operation, 1 = line by line operation. When line by line operation is selected MONO is forced to 1 and CHAN[1:0] to 00 internally, ensuring that the correct internal timing signals are produced. Green and Blue PGAs are also disabled to save power. 1 ACYCNRLC 0 When LINEBYLINE = 0 this bit has no effect. When LINEBYLINE = 1 this bit determines the function of the RLC/ACYC input pin and the input multiplexer and offset/gain register controls. 0 = RLC/ACYC pin enabled for Reset Level Clamp. Internal selection of input and gain/offset multiplexers, 1 = Auto-cycling enabled by pulsing the RLC/ACYC input pin. See Table 4, Colour Selection Description in Line-by-Line Mode for colour selection mode details. When auto-cycling is enabled, the RLC/ACYC pin cannot be used for reset level clamping. The RLCINT bit may be used instead. 2 FME 0 When LINEBYLINE = 0 this bit has no effect. When LINEBYLINE = 1 this bit controls the input force mux mode: 0 = No force mux, 1 = Force mux mode. Forces the input mux to be selected by FM[1:0] separately from gain and offset multiplexers. See Table 4 for details. 3 RLCINT 0 When LINEBYLINE = 1 and ACYCNRLC = 1 this bit is used to determine whether Reset Level Clamping is used. 0 = RLC disabled, 1 = RLC enabled. 5:4 INTM[1:0] 00 Colour selection bits used in internal modes. 00 = Red, 01 = Green, 10 = Blue and 11 = Reserved. See Table 4 for details. 7:6 FM[1:0] 00 Colour selection bits used in input force mux modes. 00 = RINP, 01 = GINP, 10 = BINP and 11 = Reserved. See Table 4 for details. 0 VSMPDET 0 0 = Normal operation, signal on VSMP input pin is applied directly to Timing Control block. 1 = Programmable VSMP detect circuit is enabled. An internal synchronisation pulse is generated from signal applied to VSMP input pin and is applied to Timing Control block. 3:1 VDEL[2:0] 000 4 POSNNEG 0 When VSMPDET = 0 these bits have no effect. When VSMPDET = 1 these bits set a programmable delay from the detected edge of the signal applied to the VSMP pin. The internally generated pulse is delayed by VDEL MCLK periods from the detected edge. See Figure 19, Internal VSMP Pulses Generated for details. When VSMPDET = 0 this bit has no effect. When VSMPDET = 1 this bit controls whether positive or negative edges are detected: 0 = Negative edge on VSMP pin is detected and used to generate internal timing pulse. 1 = Positive edge on VSMP pin is detected and used to generate internal timing pulse. See Figure 19 for further details. 7:5 Reserved 000 Must be set to zero 3:0 SELDIS[3:0] 0000 Selective power disable register - activated when SELPD = 1. Each bit disables respective cell when 1, enabled when 0. SELDIS[0] = Red CDS, PGA SELDIS[1] = Green CDS, PGA SELDIS[2] = Blue CDS, PGA SELDIS[3] = ADC 7:4 Reserved 0000 Must be set to zero w PD Rev 4.6 October 2008 28 WM8196 REGISTER Production Data BIT NO BIT NAME(S) DEFAULT DESCRIPTION Offset DAC (Red) 7:0 DAC[7:0] 10000000 Red channel offset DAC value. Offset DAC (Green) 7:0 DAC[7:0] 10000000 Green channel offset DAC value Offset DAC (Blue) 7:0 DAC[7:0] 10000000 Blue channel offset DAC value Offset DAC (RGB) 7:0 DAC[7:0] 10000000 A write to this register location causes the red, green and blue offset DAC registers to be overwritten by the new value PGA gain (Red) 7:0 PGA[7:0] 00000000 Determines the gain of the red channel PGA according to the equation: Red channel PGA gain = 208/(283-PGA[7:0]) PGA gain (Green) 7:0 PGA[7:0] 00000000 Determines the gain of the green channel PGA according to the equation: Green channel PGA gain = 208/(283-PGA[7:0]) PGA gain (Blue) 7:0 PGA[7:0] 00000000 Determines the gain of the blue channel PGA according to the equation: Blue channel PGA gain = 208/(283-PGA[7:0]) PGA gain (RGB) 7:0 PGA[7:0] 00000000 A write to this register location causes the red, green and blue PGA gain registers to be overwritten by the new value Table 7 Register Control Bits w PD Rev 4.6 October 2008 29 WM8196 Production Data APPLICATIONS INFORMATION RECOMMENDED EXTERNAL COMPONENTS DVDD1 DVDD2 3 10 C1 DVDD1 8 DGND DVDD2 C2 AVDD 21 C3 AGND1 AVDD 22 2 AGND2 DGND AGND AGND 1 Video Inputs 28 27 26 C9 VRT RINP VRX GINP VRB BINP 24 C4 25 C5 23 C6 C7 C8 VRLC/VBIAS AGND WM8196 AGND OP[7]/SDO 7 Timing Signals 5 6 MCLK OP[6] VSMP OP[5] RLC/ACYC OP[4] OP[3] 12 11 9 Interface Controls 4 SCK OP[2] SDI OP[1] SEN OP[0] 20 DVDD1 DVDD2 19 18 Output Data Bus 17 16 15 + C10 + C11 DGND 14 AVDD + C12 AGND 13 OEB NOTES: 1. C1-9 should be fitted as close to WM8196 as possible. 2. AGND and DGND should be connected as close to WM8196 as possible. Figure 26 External Components Diagram RECOMMENDED EXTERNAL COMPONENT VALUE COMPONENT REFERENCE SUGGESTED VALUE DESCRIPTION C1 100nF De-coupling for DVDD1. C2 100nF De-coupling for DVDD2. C3 100nF De-coupling for AVDD. C4 10nF High frequency de-coupling between VRT and VRB. C5 1μF C6 100nF De-coupling for VRB. C7 100nF De-coupling for VRX. C8 100nF De-coupling for VRT. C9 100nF De-coupling for VRLC. C10 10μF Reservoir capacitor for DVDD1. C11 10μF Reservoir capacitor for DVDD2. C12 10μF Reservoir capacitor for AVDD. Low frequency de-coupling between VRT and VRB (non-polarised). Table 8 External Components Descriptions w PD Rev 4.6 October 2008 30 WM8196 Production Data PACKAGE DIMENSIONS DS: 28 PIN SSOP (10.2 x 5.3 x 1.75 mm) b DM007.E e 28 15 E1 1 D E GAUGE PLANE 14 c A A2 A1 Θ L 0.25 L1 -C0.10 C Symbols A A1 A2 b c D e E E1 L L1 θ MIN ----0.05 1.65 0.22 0.09 9.90 7.40 5.00 0.55 o 0 REF: Dimensions (mm) NOM --------1.75 0.30 ----10.20 0.65 BSC 7.80 5.30 0.75 1.25 REF o 4 SEATING PLANE MAX 2.0 0.25 1.85 0.38 0.25 10.50 8.20 5.60 0.95 o 8 JEDEC.95, MO-150 NOTES: A. ALL LINEAR DIMENSIONS ARE IN MILLIMETERS. B. THIS DRAWING IS SUBJECT TO CHANGE WITHOUT NOTICE. C. BODY DIMENSIONS DO NOT INCLUDE MOLD FLASH OR PROTRUSION, NOT TO EXCEED 0.20MM. D. MEETS JEDEC.95 MO-150, VARIATION = AH. REFER TO THIS SPECIFICATION FOR FURTHER DETAILS. w PD Rev 4.6 October 2008 31 WM8196 Production Data IMPORTANT NOTICE Wolfson Microelectronics plc (“Wolfson”) products and services are sold subject to Wolfson’s terms and conditions of sale, delivery and payment supplied at the time of order acknowledgement. Wolfson warrants performance of its products to the specifications in effect at the date of shipment. Wolfson reserves the right to make changes to its products and specifications or to discontinue any product or service without notice. Customers should therefore obtain the latest version of relevant information from Wolfson to verify that the information is current. Testing and other quality control techniques are utilised to the extent Wolfson deems necessary to support its warranty. Specific testing of all parameters of each device is not necessarily performed unless required by law or regulation. 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