Integrated Circuit Systems, Inc. ICS1523 High-Performance Programmable Line-Locked Clock Generator General Description Features The ICS1523 is a low-cost but very high-performance frequency generator for line-locked and genlocked highresolution video applications. Using ICSs advanced low-voltage CMOS mixed-mode technology, the ICS1523 is an effective clock solution for video projectors and displays at resolutions from VGA to beyond UXGA. Pixel clock frequencies up to 250 MHz Very low jitter Dynamic Phase Adjust (DPA) for clock outputs Balanced PECL differential outputs Single-ended SSTL_3 clock outputs Double-buffered PLL/DPA control registers Independent software reset for PLL/DPA External or internal loop filter selection Uses 3.3Vdc. Inputs are 5V-tolerant. I2C-bus serial interface can run at either low speed (100 kHz) or high speed (400 kHz). Lock detection 24-pin 300-mil SOIC package The ICS1523 offers pixel clock outputs in both differential (to 250 MHz) and single-ended (to 150 MHz) formats. Dynamic Phase Adjust circuitry allows user control of the pixel clock phase relative to the recovered sync signal. A second differential output at half the pixel clock rate enables deMUXing of multiplexed analog-to-digital converters. The FUNC pin provides either the regenerated input from the phase-locked loop (PLL) divider chain output or a re-synchronized and sharpened input HSYNC. The advanced PLL uses either its internal programmable feedback divider or an external divider. The device is programmed by a standard I2C-bus serial interface and is available in a 24-pin wide small-outline integrated circuit (SOIC) package. Block Diagram Applications LCD monitors and video projectors Genlocking multiple video subsystems Frequency synthesis Pin Configuration 24-Pin SOIC 2 I C-bus is a trademark of Philips Corporation. Dynamic Phase Adjust is a trademark of Integrated Circuit Systems, Inc. ICS1523 Rev S 5/21/99 ICS reserves the right to make changes in the device data identified in this publication without further notice. ICS advises its customers to obtain the latest version of all device data to verify that any information being relied upon by the customer is current and accurate. ICS1523 Document Revision History Rev P (First Release) Pin Descriptions changed to add type column. (pg 3) Added SDA and AC Input Characteristics. (pg 18) Changed VCO Output, Intrinsic Jitter graph to show slow and fast cases (pg 19) Timing diagram changes to reference t0 to REF and notes on test conditions added (pg 22) Lock Renamed Lock/Ref (Throughout). General cleanup for readability. Rev Q Rev R Rev S Added typical external loop filter values. (pg 17) Added section on power supply considerations and SSTL_3 outputs. (pg 18) Correct labels and scale on VCO Output, Intrinsic Jitter graph. (pg 20) Correct depiction of timing diagram and added typical transition timing. (pg 23) Added Document Revision History. (pg 25) Change to descriptions for pins 20 to 23. (pg 3) Change to description for Reg 0h bits 0 and 1, added table. (pg 6) Within table for Reg 0h bits 6 and 7, changed Osc_En to IN_SEL . (pg 6) Moved Reg 0 bits 4 through 7 from pg 6 to new pg 7. Change to Software Programming Flow diagram. (pg 13). Added under Absolute Maximum Ratings ESD ratings and warning. (pg 19) Under Recommend Operating Conditions, PECL Outputs, Output Low Voltage, added a note and added a new page. (pg 19) Under Recommend Operating Conditions, SSTL-3 Outputs, Output Low Voltage, changed direction of symbols. (pg 19) Change to VCO Output Frequency and Intrinsic Jitter graph to reflect correct VCO frequency (pg 20) Moved Revision History from last page of data sheet to second page. (pg 2) In Layout Guideline 2, changed shunt capacitor value from 150 pF to 33 pF. (pg 19) Changed various cross-references within Layout Guidelines. (pg 19) 2 ICS1523 Overview Dynamic Phase Adjust The Dynamic Phase Adjust allows addition of a programmable delay to the pixel clock output, relative to the recovered HSYNC signal. The ability to add delays is particularly useful when multiple video sources must be synchronized. A delay of up to one pixel clock period is selectable in the following increments: 1/64 period for pixel clock rates to 40 MHz 1/32 period for pixel clock rates to 80 MHz 1/16 period for pixel clock rates to 160 MHz The ICS1523 addresses stringent graphics system line-locked and genlocked applications and provides the clock signals required by high-performance video analog-to-digital converters. Included are a phase-locked loop (PLL) with a 500-MHz voltage controlled oscillator (VCO), a Dynamic Phase Adjust to provide a user-programmed pixel clock delay, the means for deMUXing multiplexed ADCs, and both balanced-programmable (PECL) and single-ended (SSTL_3) high-speed clock outputs. Phase-Locked Loop The phase-locked loop is optimized for line-locked applications, for which the inputs are horizontal sync signals. A high-performance Schmitt trigger preconditions the HSYNC input, whose pulses can be degraded if they are from a remote source. This preconditioned HSYNC signal is provided as a clean reference signal with a short transition time. (In contrast, the signal that a typical PC graphics card provides has a transition time of tens of nanoseconds.) Output Drivers and Logic Inputs The ICS1523 utilizes low-voltage TTL (LVTTL) inputs as well as SSTL_3 (EIA/JESD8-8) and low-voltage PECL (pseudoECL) outputs, operating at 3.3-V supply voltage. The LVTTL inputs are 5 V-tolerant. The SSTL_3 and differential PECL output drivers drive resistive terminations or transmission lines. At lower clock frequencies, the SSTL_3 outputs can be operated unterminated. A second high-frequency input such as a crystal oscillator and a 7-bit programmable divider can be selected. This selection allows the loop to operate from a local source and is also useful for evaluating intrinsic jitter. I2C-bus Serial Interface The ICS1523 utilizes the industry-standard I2C-bus serial interface. The interface uses 12 registers: one write-only, eight read/write, and three read-only. Two ICS1523 devices can be addressed, according to the state of the I2CADR pin. When the pin is low, the read address is 4Dh, and the write address is 4Ch. When the pin is high, the read address is 4Fh, and the write address is 4Eh. The I2C-bus serial interface can run at either low speed (100 kHz) or high speed (400 kHz) and provides 5V-tolerant input. A 12-bit programmable feedback divider completes the loop. Designers can substitute an external divider. Either the conditioned HSYNC input or the loop output (recovered HSYNC) is available at the FUNC pin, aligned to the edge of the pixel clock. Automatic Power-On Reset Detection The ICS1523 has automatic power-on reset detection circuitry and it resets itself if the supply voltage drops below threshold values. No external connection to a reset signal is required. 3 ICS1523 Pin Descriptions PIN NO. P I N NA M E TYPE DESCRIPTION COMMENTS 1 VDDD PWR Digital supply 2 VSSD PWR Digital ground 3 S DA IN/OUT Serial data I2 C-bus1 4 SCL IN Serial clock I2 C-bus1 5 PDEN IN PFD enable S u s p e n d s c h a rg e p u m p 1 6 EXTFB IN External feedback in External divider input to P F D 1 7 HSYNC IN Horizontal sync Clock input to PLL1 8 EXTFIL IN External filter External PLL loop filter IN 3.3V to digital sections 9 XFILRET External filter return External PLL loop filter return 10 V D DA PWR Analog supply 3.3V for analog circuitry 11 VSSA PWR Analog ground Ground for analog circuitry 12 OSC Oscillator Input from crystal oscillator package1 , IN 2 2 13 14 I2 CADR LOCK/REF (SSTL) IN OUT I2 C address Chip I C address select Low = 4Dh read, 4Ch write High = 4Fh read, 4Eh write Lock indicator/reference Displays PLL or DPA lock or REF input 15 FUNC (SSTL) OUT Function output SSTL_3 selectable HSYNC output 16 CLK/2 (SSTL) OUT P i xe l c l o c k / 2 o u t SSTL_3 driver to ADC deMUX input 17 CLK (SSTL) OUT P i xe l c l o c k o u t SSTL_3 driver to ADC 18 VDDQ PWR Output driver supply 3.3V to output drivers 19 VSSQ PWR Output driver ground Ground for output drivers 20 CLK- (PECL) OUT P i xe l c l o c k o u t Inverted PECL driver to ADC. Open drain. 21 CLK+ (PECL) OUT P i xe l c l o c k o u t PECL driver to ADC. Open drain. P i xe l c l o c k / 2 o u t Inverted PECL driver to ADC deMUX input. Open drain. 22 CLK/2- (PECL) OUT 23 CLK/2+ (PECL) OUT P i xe l c l o c k / 2 o u t PECL driver to ADC deMUX input. Open drain. 24 IREF IN Reference current Reference current for PECL outputs Notes: 1. These LVTTL inputs are 5 V-tolerant. 2. Connect to ground if unused. 4 ICS1523 Block Diagram 5 ICS1523 I2C Register Map Summary Register Index 0h 1h Name Input Control Loop Control Access R/W R/W* 2h FdBk Div 0 R/W* 3h FdBk Div 1 R/W* 4h 5h DPA Offset DPA Control R/W Bit Name Bit # Reset Value PDen 0 1 Phase Detector Enable (0=External Enable, 1=Always Enabled) PD_Pol 1 0 Phase Detector Enable Polarity (0=Not Inverted, 1=Inverted) Ref_Pol 2 0 External Reference Polarity (0=Positive Edge, 1=Negative Edge) Fbk_Pol 3 0 External Feedback Polarity (0=Positive Edge, 1=Negative Edge) Fbk_Sel 4 0 External Feedback Select (0=Internal Feedback, 1=External) Func_Sel 5 0 Function Out Select (0=Recovered HSYNC, 1=Input HSYNC) EnPLS 6 1 Enable PLL Lock/Ref Status Output (0=Disable 1=Enable) EnDLS 7 0 Enable DPA Lock/Ref Status Output (0=Disable 1=Enable) PFD0-2 0-2 0 Phase Detector Gain Reserved 3 0 Reserved PSD0-1 4-5 0 Post-Scaler Divider (0 = /2, 1 = /4, 2 = /8, 3 = /16) Reserved 6-7 0 Reserved FBD0-7 0-7 FF 7h 8h Output Enables FBD8-11 0-3 F PLL Feedback Divider MSBs (bits 8-11) * 4-7 0 Reserved DPA_OS0-5 0-5 0 Dynamic Phase Aligner Offset Reserved 6 0 Reserved Fil_Sel 7 0 Loop Filter Select (0=External, 1=Internal) R / W ** DPA_Res0-1 Osc_Div Reset R/W R/W Write PLL FeedBack Divider LSBs (bits 0-7) * Reserved Metal_Rev 6h Description 0-1 3 DPA Resolution (0=16 delay elements, 1=32, 2=Reserved, 3=64) 2-7 0 Metal Mask Revision Number OE_Pck 0 0 Output Enable for PECL PCLK Outputs ( 0=High Z, 1=Enabled) OE_Tck 1 0 Output Enable for STTL_3 CLK Output ( 0=High Z, 1=Enabled) OE_P2 2 0 Output Enable for PECL CLK/2 Outputs ( 0=High Z, 1=Enabled) OE_T2 3 0 Output Enable for STTL_3 CLK/2 Output ( 0=High Z, 1=Enabled) OE_F 4 0 Output Enable for STTL_3 FUNC Output ( 0=High Z, 1=Enabled) Ck2_Inv 5 0 CLK/2 Invert (0=Not Inverted, 1= Inverted) Out_Scl 6-7 0 SSTL Clock Scaler (0 = /1, 1 = /2, 2 = /4, 3 = /8) Osc_Div 0-6 0-6 0 Osc Divider modulus In-Sel 7 1 Input Select (0=HSYNC Input, 1=Osc Divider) DPA 0-3 x Writing xAh resets DPA and loads working register 5 PLL 4-7 x Writing 5xh resets PLL and loads working registers 1-3 10h Chip Ver Read Chip Ver 0-7 17 Chip Version 23 Dec (17 Hex) as in 1523 11h Chip Rev Read Chip Rev 0-7 01 Initial value 01h. Value Increments with each all-layer change. 12h Rd_Reg Read DPA_Lock 0 N/A DPA Lock Status (0=Unlocked, 1=Locked) PLL_Lock 1 N/A PLL Lock Status (0=Unlocked, 1=Locked) Reserved 2-7 0 Reserved * Identifies double-buffered registers. Working registers are loaded during software PLL reset. ** Identifies double-buffered register. Working registers are loaded during software DPA reset. 6 ICS1523 Detailed Register Description Name: Register: Index: Input Control 0h Read / Write Bit Name Bit # Reset Value Description PDen PD_Pol Ref_Pol Fbk_Pol Fbk_Sel Func_Sel EnPLS EnDLS 0 1 2 3 4 5 6 7 1 0 0 0 0 0 1 0 Bit Name Description 0 PDen Phase/Frequency Detector Enable Phase/Frequency Detector Enable Phase/Frequency Detector Enable Polarity Phase/Frequency Detector External Reference Polarity External Reference Feedback Polarity External Feedback Select Function Output Select Enable PLL Lock Status Output on LOCK/REF pin Enable DPA Lock Status Output on LOCK/REF pin PDen PD_Pol 0 X 1 0 1 0 P h a s e / F r e q u e n cy D e t e c t o r Is Enabled When: PDEN= 1 A lwa y s ( D e fa u l t ) PDEN = 0 1 PD_Pol Phase/Frequency Detector Enable Polarity 2 Ref_Pol Phase/Frequency Detector External Reference Polarity Edge of input signal on which Phase Detector triggers. 0 = Rising Edge (default) 1 = Falling Edge 3 Fbk_Pol External Reference Feedback Polarity Edge of EXTFB (pin 6) signal on which Phase/Frequency Detector triggers when external feedback is used (Reg0 [4]=1). 0 = Positive Edge (default) 1 = Negative Edge Table continues on next ppage 7 ICS1523 Name: Input Control Register: 0 h Bit Name Description 4 Fbk_Sel External Feedback Select 0 = Internal Feedback (default) 1 = External Feedback 5 Func_Sel Function Output Select Selects re-clocked output to FUNC (pin 15). 0 = Recovered HSYNC (default). Re-generated HSYNC output. 1 = External HSYNC. Schmitt-trigger conditioned input from HSYNC (pin 7). 6 EnPLS Enable PLL Lock Status Output on LOCK/REF pin 7 EnDLS Enable DPA Lock Status Output on LOCK/REF pin EnPLS EnDLS IN_SEL LOCK/REF(14) 0 0 N/A 0 0 1 N/A 1 if DPA locked, 0 otherwise 1 0 N / A 1 i f P L L l o c ke d , 0 o t h e r w i s e Post Schmitt trigger 1 1 0 HSYNC(7) XOR Ref_Pol 1 1 1 Fosc Osc_Div Bits 6,7 enable multiple functions at LOCK/REF, (pin 14) 8 ICS1523 Name: Register: Index: Loop Control Register 1h Read / Write* Bit Name Bit # Reset Value Description PFD0-2 Reserved PSD 0-1 Reserved 0-2 3 4-5 6-7 0 0 0 0 Phase Frequency Detector Gain Reserved Post-Scaler Divider Reserved Bit Name Description 0-2 PFD0-2 Phase/Frequency Detector Gain 3 Reserved 4-5 PSD 0-1 6-7 Bit 2 Bit 1 Bit 0 PFD Ga i n ( A/ 2 r a d) 0 0 0 0 1 1 1 1 0 0 1 1 0 0 1 1 0 1 0 1 0 1 0 1 1 2 4 8 16 32 64 128 Post-Scaler Divider Divides the output of the VCO to the DPA and Feedback Divider. Bit 5 Bit 4 PSD Divider 0 0 1 1 0 1 0 1 2 (default) 4 8 16 Reserved * Double-buffered register. Actual working registers are loaded during software PLL reset. See register 8h for details. 9 ICS1523 Name: Register: Index: Feedback Divider 0 Register / Feedback Divider 1 Register 2h, 3h Read / Write* Bit Name Index Bit # Reset Value FBD 0-7 2 0 -7 FF FBD 8 -11 Reserved 3 3 0 -3 4 -7 F Description PLL Feedback Divider LSBs (0 -7).* When Bit 0 = 0, then the total number of pixels is even. When Bit 0 = 1, then the total number of pixels is odd. PLL Feedback Divider MSBs (8 -11)* Reserved The value that is programmed into these two registers, plus a value of 8, defines the total number of clock periods that the ICS 1523 generates between HSYNCs. Program these registers with the total number of horizontal pixels per line minus 8. Feedback Divider Modulus = Reg 3 2 1 3 0 7 6 5 Reg 2 4 3 2 1 0 +8 12 Feedback Divider Modulus 4103 * Double-buffered registers. Actual working registers are loaded during software PLL reset. See Register 8h for details. Name: Register: Index: DPA Offset Register 4h Read / Write Bit Name Bit # Reset Value DPA_OS0-5 Reserved Fil_Sel Bit 0-5 6 7 Name 0 0 0 Description Dynamic Phase Adjust Offset Reserved Loop Filter Select Description 0-5 DPA_OS0-5 Dynamic Phase Adjust Offset. Selects clock edge offset in discrete steps from zero to one clock period minus one step. Resolution (number of delay elements per clock cycle) is selected by DPA_Res0-1 (Reg 5:0-1). Note: Offsets equal to or greater than one clock period are neither recommended nor supported. Example: For DPA_Res0-1=01H, the clock can be delayed from 0 to 31 steps. 7 Fil_Sel Selects external loop filter (0) or internal loop filter (1). The use of an external loop filter is strongly recommended for all designs. Suggested component values are available from the ICS1523 Demo Board Guide (1523DB.pdf) or the ICS1523 Register Tool (inst1523.exe) available on our web site at: (http://www.icst.com/products/pinfo/1523.htm). 10 ICS1523 Name: Register: Index: DPA Control Register 5h Read / Write* Bit Name Bit # Reset Value DPA_Res 0-1 Metal_Rev 0-1 2- 7 Description 3 0 Dynamic Phase Adjust Resolution Select. Metal Mask Revision Number. Bit Name Description 0-1 DPA_Res 0 -1 Dynamic Phase Adjust (DPA) Resolution Select. It is not recommended to use the DPA above 160 MHz. Bit 1 0 0 1 1 2-7 Metal_Rev Bit 0 0 1 0 1 CLK Range, MHz 48 24 80 Delay Elements 16 32 Reserved 64 12 160 40 Metal Mask Revision Number. After power-up, register bits 7:2 must be written with 111111. After this write, a read indicates the metal mask revision, as below. Revision Bit 7 Bit 6 Bit 5 Bit 4 Bit 3 Bit 2 A B C1 C2 D E F G 1 0 1 0 1 1 1 1 1 1 0 0 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 0 1 1 1 1 1 1 1 1 0 * Double-buffered register. Actual working registers are loaded during software DPA reset. See register 8h for details. 11 ICS1523 Name: Register: Index: Output Enable Register 6h Read / Write Bit Name Bit # Reset Value Description OE_Pck OE_Tck OE_P2 OE_T2 OE_F Ck2_Inv Out_Scl 0 1 2 3 4 5 6-7 0 0 0 0 0 0 0 Output Enable for CLK Outputs (PECL) Output Enable for CLK Output (SSTL_3) Output Enable for CLK/2 Outputs (PECL) Output Enable for CLK2 Output (SSTL_3) Output Enable for FUNC Output (SSTL_3) CLK/2 Invert CLK Scaler Bit Name Description 0 OE_Pck Output Enable for CLK Outputs (PECL) 0 = High Z 1 = Enabled 1 OE_Tck Output Enable for CLK Output (SSTL_3) 0 = High Z 1 = Enabled 2 OE_P2 Output Enable for CLK/2 Outputs (PECL) 0 = High Z 1 = Enabled 3 OE_T2 Output Enable for CLK/2 Output (SSTL_3) 0 = High Z 1 = Enabled 4 OE_F Output Enable for FUNC Output (SSTL_3) 0 = High Z 1 = Enabled 5 Ck2_Inv CLK/2 Invert 0 = Not Inverted 1 = Inverted 6 -7 Out_Scl Clock (CLK) Scaler Bit 7 Bit 6 CLK Divider 0 0 1 1 0 1 0 1 1 2 4 8 12 ICS1523 Name: Register: Index: Oscillator Divider Register 7h Read / Write Bit Name Bit # Reset Value Osc_Div 0-6 In_Sel 0-6 7 0 1 Description Osc Divider Modulus Input Select Bit Name Description 0-6 Osc_Div 0-6 Oscillator Divider Modulus. Divides the input from OSC (pin 12) by the set modulus. The modulus equals the programmed value, plus 2. Therefore, the modulus range is from 3 to 129. 7 In_Sel Input Select Selects the input to the Phase/Frequency Detector 0 = HSYNC 1 = Osc Divider Name: Register: Index: RESET Register 8h Write Bit Name Bit # Reset Value DPA Reset PLL Reset 0 -3 4 -7 x x Description Writing xAh to this register resets DPA working register 5 Writing 5xh to this register resets PLL working registers 1-3 Bit Name Description 0 -3 DPA Writing xAh to this register resets DPA working register 5 4 -7 PLL Writing 5xh to this register resets PLL working registers 1-3 Value Resets xA 5x 5A DPA PLL DPA and PLL 13 ICS1523 Name: Register: Index: Bit Name Chip Version Register 10 h Read Bit # Reset Value 0-7 17 Chip Ver Name: Register: Index: Bit Name Bit Name DPA_Lock PLL_Lock Reserved Chip Version 23 (17h ) Chip Revision Register 11h Read Bit # Reset Value 0 -7 01+ Chip Rev Name: Register: Index: Description Description Initial value 01h. +Value increments with each all-layer change. Status Register 12 h Read Bit # Reset Value 0 1 2 -7 N/A N/A 0 Description DPA Lock Status PLL Lock Status Reserved Bit Name Description 0 DPA_Lock DPA Lock Status. (Refer to Register 0h, bits 6 and 7.) 0 = Unlocked 1 = Locked 1 PLL_Lock PLL Lock Status. (Refer to Register 0h, bits 6 and 7.) 0 = Unlocked 1 = Locked 2 -7 Reserved 14 ICS1523 ICS1523 Software Programming Flow 15 ICS1523 I2C Data Characteristics Bit transfer on the I2C-bus START and STOP conditions Acknowledge on the I2C-bus These waveforms are from "The I 2 C-bus and how to use it," published by Philips Semiconductor. The document can be obtained from http://www-us2.semiconductors.philips.com/acrobat/various/i2c_bus_specification_1995.pdf 16 ICS1523 I2C Data Format RANDOM REGISTER WRITE PROCEDURE S 0 1 0 0 1 1 x W A 7 bit address START condition A register address Acknowledge WRITE command A P data Acknowledge STOP condition Acknowledge RANDOM REGISTER READ PROCEDURE S 0 1 0 0 1 1 X W A 7 bit address START condition register address Acknowledge WRITE command A S 0 1 0 0 1 1 X R A 7 bit address data Repeat START Acknowledge Acknowledge READ command A P STOP condition NO Acknowledge SEQUENTIAL REGISTER WRITE PROCEDURE S 0 1 0 0 1 1 X W A 7 bit address START condition A register address Acknowledge WRITE command A data Acknowledge A data Acknowledge A P Acknowledge Acknowledge STOP condition SEQUENTIAL REGISTER READ PROCEDURE S 0 1 0 0 1 1 X W A 7 bit address START condition Direction: register address Acknowledge WRITE command From bus host to device A S 0 1 0 0 1 1 X R A 7 bit address data Repeat START Acknowledge Acknowledge READ command A A P data NO Acknowledge Acknowledge STOP condition From device to bus host Note: 1. All values are transmitted with the most-significant bit first and the least-significant bit last. 2. The value of the X bit equals the logic state of pin 13 (I2CADR). 3. R = READ = 1 and W = WRITE = 0 17 ICS1523 ICS1523 Video Mode Reference Table The use of an external loop filter is strongly recommended in All Designs. The ICS1523 Video Mode Reference Table (previously included in this data sheet) lists information on the various video modes that can be used with the ICS1523. To reference this table, see the ICS1523 Demo Board Guide (1523DB.pdf) available on our web site at: (http://www.icst.com) under the ICS1523 area. 18 ICS1523 General Layout Guidelines Use a PC board with at least four layers: one power, one ground, and two signal. No special cutouts are required for power and ground planes. All supply voltages must be supplied from a common source and must ramp up together. Flux and other board surface debris can degrade the performance of the external loop filter. Ensure that the 1523 area of the board is free of contaminants. 5. PECL Outputs Implement these outputs as microstrip transmission lines. The trace widths shown are for 75 W characteristic impedance, presuming .067 in. between layers. Locate the optional series snubbing resistors as close as possible to the pins. If the termination resistors are included on-board, locate them as close as possible to the load and connect directly to the power and ground planes. [These termination resistors are omitted if the load device implements them internally. For details, see the ICS application note on microstrip and striplines (1572AN1) and within the ICS1523 Applications Guide, the application note on Designing a Custom Interface for the ICS1523 (1523AN4.)] Specific Layout Guidelines 1. Digital Supply (VDD) Bypass pin 1 (VDD) to pin 2 (VSS) with 4.7-F and 0.1-F capacitors, located as close as possible to the pins. Traces must be maximally wide and include multiple surface-etched vias to the appropriate plane. 6. Output Driver Supply Bypass pin 18 (VDDQ) to pin 19 (VSSQ) with 4.7-F and 0.1-F capacitors, located as close as possible to the pins. Traces must be maximally wide and include multiple surface-etched vias to the appropriate plane. 2. External Loop Filter The use of an external loop fil- ter is strongly recommended in All Designs. Locate loop filter components as close to pins 8 and 9 (EXTFIL and EXTFILRET) as possible. Typical loop filter values are 6.8K W for the series resistor, 3300 pF RF-type capacitor for the series capacitor, and 33 pF for the shunt capacitor. (For details, see the Frequently Asked Questions part of the ICS1523 Applications Guide, FAQ2 and FAQ3.). 7. SSTL_3 Outputs SSTL_3 outputs can be used like conventional CMOS rail-to-rail logic or as a terminated transmission line system at higher-output frequencies. With terminated outputs, the considerations of item 5, PECL Outputs apply. See JEDEC documents JESD8-A and JESD8-8. 3. Analog PLL Supply (VDDA) Decouple pin 10 (VDDA) with a series ferrite bead. Bypass the supply end of the bead with 4.7-F and 0.1-F capacitors. Bypass pin 10 to pin 11 (VSSA) with a 0.1-F capacitor. Locate these components as close as possible to the pins. Traces must be maximally wide and have multiple surface-etched vias to the . power or ground planes. 4 4. PECL Current Set Resistor Locate PECL currentset resistor as close as possible to pin 24 (IREF). Bypass pin 24 to ground with a 0.1-F capacitor. 2 3 1 5 ICS1523 1 6 7 Note: Drawing is not to scale. It is for illustrative purposes only. 19 ICS1523 Power Supply Considerations The ICS1523 incorporates special internal power-on reset circuitry that requires no external reset signal connection. The supply voltage (VDD) must remain within the recommended operating conditions during normal operation. To reset the ICS1523, the supply voltage at the part must be reduced below the threshold voltage (Vth) of the power-on reset circuit. The supply voltage must remain below that threshold voltage such that board power conditioning capacitors are drained and the proper reset state is latched. The amount of time (td) to hold the voltage in a reset state varies with the design. However, a typical value of 10 ms should be sufficient. SSTL_3 Outputs Unterminated Outputs In the ICS1523, unterminated SSTL output pins display exponential transitions similar to those of rectangular pulses presented to RC loads. The 10-90% rise time is typically 1.6 ns, and the corresponding fall time is typically 700 ps. In turn, this asymmetry contributes to duty cycle asymmetry at higher output frequencies. In the absence of significant load capacitance (which can further increase rise and fall time), this asymmetry is the dominant factor determining high-frequency performance of these singleended outputs. Typically, no termination is required either for the LOCK/REF, FUNC, and CLK/2 outputs or for CLK outputs up to approximately 135 MHz. Terminated Outputs SSTL_3 outputs are intended to terminate in low impedances to reduce the effect of external circuit capacitance. Use of transmission line techniques enables use of longer traces between source and driver without increasing ringing due to reflections. Where external capacitance is minimal and substantial voltage swing is required to meet LVTTL VIH and VOL requirements, the intrinsic rise and fall times of ICS1523 SSTL outputs are only slightly improved by termination in a low impedance. The ICS1523 SSTL output source impedance is typically less than 60W. Termination impedance of 100W reduces output swing by less than 30% which is more than enough to drive a single load of LVTTL inputs. 20 ICS1523 Absolute Maximum Ratings VDD, VDDA, VDDQ (measured to VSS) . . . . . . . . . . . . . . . . . 4.3 V Digital Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VSS 0.3V to 5.5 V Analog Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VSSA 0.3 V to VDDA +0.3 V Digital Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VSSQ 0.3 V to VDDQ +0.3 V Storage Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 65C to +150C Junction Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 175C Soldering Temperature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260C ESD Susceptibility* . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . > 2 KV (*Electrostatic-sensitive devices. Do not open or handle except in a static-free workstation.) 21 ICS1523 Recommended Operating Conditions VDD, VDDQ, VDDA (measured to VSS) . . 3.0 to 3.6 V Operating Temperature (Ambient) . . . . . . . . . 0 to +70C D C S u p p l y C u r re n t PA R A M E T E R SYMBOL CONDITIONS MIN MAX UNITS Supply Current, Digital IDDD VDDD = 3.6V -- 25 mA Supply Current, Output Drivers IDDQ VDDQ = 3.6V, no output drivers enabled. -- 6 mA Supply Current, Analog I D DA VDDA = 3.6V -- 5 mA MIN MAX UNITS D i g i t a l I n p u t s ( S DA , S C L , P D E N , E X T F B , H S Y N C , O S C , PA R A M E T E R SYMBOL I 2C A D R ) CONDITIONS Input High Voltage VIH 2 5.5 V Input Low Voltage VIL VSS-0.3 0.8 V Input Hysteresis IIH VIH = VDD Input Low Current IIL VIL = 0 Input Capacitance Cin Input High Current 0.2 0.6 V -- 10 A -- 200 A -- 10 pF MIN MAX UNITS 0.4 V MIN MAX UNITS S DA ( I n O u t p u t M o d e : S DA i s B i d i re c t i o n a l ) PA R A M E T E R Output Low Voltage SYMBOL VOL CONDITIONS IOUT = 3 mA. VOH = 6.0V maximum as determined by the external pull-up resistor. PECL Outputs (CLK+, CLK-, CLK/2+, CLK/2-) PA R A M E T E R SYMBOL CONDITIONS Output High Voltage Output Low Voltage (Note: VOL must not fall below the level given so that the correct value for IOUT can be maintained.) VOH IOUT = 0 -- VDD V VOL IOUT = programmed value 1.0 -- V MIN MAX UNITS -- 80 W SSTL-3 Outputs (CLK, CLK/2, FUNC, LOCK/REF) PA R A M E T E R Output Resistance SYMBOL RO CONDITIONS 1 <VO<2V AC Input Characteristics PA R A M E T E R HSYNC Input Frequency OSC Input Frequency SYMBOL MIN MAX UNITS fHSYNC Reg 7:7 = 0 CONDITIONS .008 10 MHz fOSC Reg 7:7 = 1 .02 100 MHz 22 ICS1523 VCO Output Frequency and Intrinsic Jitter 700 700 600 600 Frequency (Slow: 3.0V @ 70C) Frequency (Nominal: 3.3V @ 30C) Frequency (Fast: 3.6V @ 0C) 500 Jitter (3.0V @ 70C) Jitter (3.3V @ 30C) Jitter (3.6V @ 0C) 400 400 Frequency 300 300 200 200 Jitter 100 100 0 0 0 0.2 0.4 0.6 0.8 1 1.2 1.4 1.6 1.8 VCO Voltage 23 2 2.2 2.4 2.6 2.8 3 3.2 Jitter (ps) VCO Frequency (MHz) 500 ICS1523 ns Delay DPA Delay-16 Element Resolution 20 18 16 14 12 10 8 6 4 2 0 50 MHz - SVGA @ 72 Hz 157.5 MHz - SXGA @ 85 Hz 0 4 8 16 12 DPA Setting DPA Delay - 32 Element Resolution 45 ns Delay 40 35 25.175 MHz - VGA @ 60 Hz 30 78.75 MHz - XGA @ 75 Hz 25 20 15 10 5 0 0 4 8 12 16 20 24 32 28 DPA Setting DPA Delay - 64 Element Resolution 90 80 ns Delay 70 12.27 MHz - NTSC 60 39.8 MHz - SVGA @ 60 50 40 30 20 10 0 0 4 8 12 16 20 24 Note: Maximum number of data points used for this graph. 28 32 36 DPA Setting 24 40 44 48 52 56 60 64 AC Timing Characteristics Overview 25 ICS1523 * Timing when Register 2, Bit 0 = 0 (Total number of pixels is even.) ** Timing when Register 2, Bit 0 = 1 (Total number of pixels is odd.) ICS1523 Output Timing Diagram Typical Transition Times* Symbol Timing Description Rise Fall Units tR REF 2.8 1.8 ns tP PECL CLK 1.0 1.2 ns tS tF SSTL-CLK FUNC_OUT 1.6 1.2 0.7 1.0 ns ns Mi n Typ Max Units Output Timing* Symbol Timing Description t0 HSYNC to REF delay 11.3 11.5 12 ns t1 REF to PECL clock delay -1.0 0.8 2.2 ns PECL clock duty cycle 45 50 55 % t4 PECL clock to SSTL_3 clock delay 0.2 0.75 1.2 ns t5 PECL clock to FUNC_OUT delay 1.5 1.9 2.3 ns t6 PECL clock to PECL/2 clock 1.0 1.3 1.5 ns t7 PECL clock to SSTL_3-CLK/2 delay 1.1 1.4 1.8 ns SSTL clock duty cycle 45 50 55 % t2, t3 t8, t9 *Note: Measured at 3.6V 0C, 135-MHz output frequency, PECL clock lines to 75W termination, SSTL_3 clock lines unterminated, 20-pF load. Transition times vary based on termination. 26 ICS1523 24-Pin SOIC (wide body) Ordering Information ICS1523M 27 ICS reserves the right to make changes in the device data identified in this publication without further notice. ICS advises its customers to obtain the latest version of all device data to verify that any information being relied upon by the customer is current and accurate.