CY28412OCT

PRELIMINARY CY28412 Clock Generator for Intel® Grantsdale Chipset Features • Supports Intel P4 and Prescott CPU • Selectable CPU frequencies • Differential CPU clock pairs • 100 MHz differential SRC clocks • 96 MHz differential dot clock • 48 MHz USB clocks • 33 MHz PCI clock CPU x2 / x3 SRC x7 / x8 PCI x8 REF x2 DOT96 x1 USB_48 x1 • Low-voltage frequency select input • I2C Support with read back capabilities • Ideal Lexmark Spread Spectrum profile for maximum electromagnetic interference (EMI) reduction • 3.3V power supply • 56-pin SSOP package Block Diagram XIN XOUT CPU_STP# PCI_STP# FS_[C:A] VTT_PWRGD# IREF Pin Configuration PCI0 PCI1 VDD_PCI VDD_CPU GND_PCI CPUT[0:1], CPUC[0:1], CPU(T/C)2_ITP] PCI2 VDD_SRC PCI3 SRCT[0:6], SRCC[0:6], PCI4 SATA[T/C] PCI5 GND_PCI VDD_PCI VDD_PCI TEST_SEL/PCIF0 PCI[0:5] ITP_EN/PCIF1 VDD_PCIF PCIF[0:1] VDD_48 USB48/FS_B GND_48 VDD_48 MHz DOT96T DOT96T DOT96C DOT96C VTT_PwrGd#/PD USB_48 SRCT0 SRCC0 SRCT1 STCC1 VDD_SRC GND_SRC SRCT2 SRCC2 SATAT SATAC VDD_REF REF[1:0] XTAL OSC PLL1 PLL Ref Freq Divider Network PD PLL2 SDATA SCLK I2C Logic 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 56 55 54 53 52 51 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 VDD_REF REF0/FS_C REF1/FS_A GND_REF X1 X2 SDATA SCLK GND_CPU CPUT0 CPUC0 VDD_CPU CPUT1 CPUC1 IREF GND_A VDD_A CPUT2_ITP/SRCT6 CPUC2_ITP/SRCC6 VDD_SRC SRCT5 SRCC5 GND_SRC SRCT4 SRCC4 SRCT3 SRCC3 VDD_SRC 56 SSOP CY28412 Rev 1.0, November 20, 2006 2200 Laurelwood Road, Santa Clara, CA 95054 Tel:(408) 855-0555 Fax:(408) 855-0550 Page 1 of 16 www.SpectraLinear.com CY28412 Pin Definitions Pin No. 47,46,44,43 39,38 CPUT/C CPUT2_ITP/SRCT6, CPUC2_ITP/SRCC6 DOT96T, DOT96C REF0/FS_C, REF1/FS_A USB48/FS_B Name Type O, DIF Differential CPU clock outputs. O, DIF Selectable Differential CPU or SRC clock output. ITP_EN = 0 @ VTT_PWRGD# assertion = SRC6 ITP_EN = 1 @ VTT_PWRGD# assertion = CPU2 O, DIF Fixed 96-MHz clock output. I/O 14.318-MHz reference clock/3.3V-tolerant input for CPU frequency selection. Input is latched upon assertion (LOW) of VTT_PWRGD#/PD Refer to DC Electrical Specifications table for Vil_FS and Vih_FS specifications. Fixed 48-MHz USB clock output/3.3V-tolerant input for CPU frequency selection. Input is latched upon assertion (LOW) of VTT_PWRGD#/PD Refer to DC Electrical Specifications table for Vil_FS and Vih_FS specifications. A precision resistor is attached to this pin, which is connected to the internal current reference. Free-running 33-MHz clocks/ 3.3V-tolerant input for selecting test mode. Input is latched upon assertion (LOW) of VTT_PWRGD#/PD 1 = All outputs are three-stated for test 0 = All outputs normal operation **This input has an internal pull-down resistor. Description 16,17 55, 54 14 I/O 42 1,2,5,6,7,8 11 IREF PCI[0:5] TEST_SEL/PCIF0 I O, SE 33-MHz clocks. I/O 12 ITP_EN/PCIF1 I/O, SE Free-running 33-MHz clock/CPU2 select (sampled on the VTT_PWRGD# assertion). 1 = CPU2_ITP, 0 = SRC6 I I/O SMBus-compatible SCLOCK. SMBus-compatible SDATA. 49 50 27,28 SCLK SDATA SATAT, SATAC O, DIF Differential serial reference clock. Recommended output for SATA. O, DIF Differential serial reference clocks. 19,20,21,22, SRCT/C[0:5] 25,26,30,31, 32,33,35,36 13 45 3,10 56 23,29,37 40 15 48 4,9 53 24,34 41 18 VDD_48 VDD_CPU VDD_PCI VDD_REF VDD_SRC VDD_A GND_48 GND_CPU GND_PCI GND_REF GND_SRC GND_A VTT_PWRGD#/PD PWR PWR PWR PWR PWR PWR GND GND GND GND GND GND I, PU 3.3V power supply for outputs. 3.3V power supply for outputs. 3.3V power supply for outputs. 3.3V power supply for outputs. 3.3V power supply for outputs. 3.3V power supply for PLL. Ground for outputs. Ground for outputs. Ground for outputs. Ground for outputs. Ground for outputs. Ground for PLL. 3.3V LVTTL input is a level sensitive strobe used to latch the REF0/FSC, REF1/FSA, USB48/FSB, TEST_SEL/PCIF0 and ITP_EN/PCIF1 inputs. After VTT_PWRGD# (active LOW) assertion, this pin becomes a realtime input for asserting power-down (active HIGH). 14.318-MHz crystal input. 52 51 X1 X2 I O, SE 14.318-MHz crystal output. Rev 1.0, November 20, 2006 Page 2 of 16 CY28412 Frequency Select Pins (FS_A, FS_B and FS_C) Host clock frequency selection is achieved by applying the appropriate logic levels to FS_A, FS_B, FS_C inputs prior to VTT_PWRGD# assertion (as seen by the clock synthesizer). Upon VTT_PWRGD# being sampled low by the clock chip (indicating processor VTT voltage is stable), the clock chip samples the FS_A, FS_B and FS_C input values. For all logic levels of FS_A, FS_B and FS_C VTT_PWRGD# employs a one-shot functionality in that once a valid low on VTT_PWRGD# has been sampled, all further VTT_PWRGD#, FS_A, FS_B and FS_C transitions will be ignored, except in test mode. izes to their default setting upon power-up, and therefore use of this interface is optional. Clock device register changes are normally made upon system initialization, if any are required. The interface cannot be used during system operation for power management functions. Data Protocol The clock driver serial protocol accepts byte write, byte read, block write, and block read operations from the controller. For block write/read operation, the bytes must be accessed in sequential order from lowest to highest byte (most significant bit first) with the ability to stop after any complete byte has been transferred. For byte write and byte read operations, the system controller can access individually indexed bytes. The offset of the indexed byte is encoded in the command code, as described in Table 2. The block write and block read protocol is outlined in Table 3 while Table 4 outlines the corresponding byte write and byte read protocol. The slave receiver address is 11010010 (D2h). Serial Data Interface To enhance the flexibility and function of the clock synthesizer, a two-signal serial interface is provided. Through the Serial Data Interface, various device functions, such as individual clock output buffers, can be individually enabled or disabled. The registers associated with the Serial Data Interface initialTable 1. Frequency Select Table (FS_A, FS_B, FS_C) FS_C 1 0 0 0 0 1 1 1 FS_B 0 0 1 1 0 0 1 1 FS_A 1 1 1 0 0 0 0 1 CPU 100 MHz 133 MHz 166 MHz 200 MHz 266 MHz 333 MHz 400 MHz Reserved SRC 100 MHz 100 MHz 100 MHz 100 MHz 100 MHz 100 MHz 100 MHz 100 MHz PCIF/PCI 33 MHz 33 MHz 33 MHz 33 MHz 33 MHz 33 MHz 33 MHz 33 MHz REF0 14.318 MHz 14.318 MHz 14.318 MHz 14.318 MHz 14.318 MHz 14.318 MHz 14.318 MHz 14.318 MHz DOT96 96 MHz 96 MHz 96 MHz 96 MHz 96 MHz 96 MHz 96 MHz 96 MHz USB 48 MHz 48 MHz 48 MHz 48 MHz 48 MHz 48 MHz 48 MHz 48 MHz Table 2. Command Code Definition Bit 7 Description 0 = Block read or block write operation, 1 = Byte read or byte write operation (6:0) Byte offset for byte read or byte write operation. For block read or block write operations, these bits should be '0000000' Table 3. Block Read and Block Write Protocol Block Write Protocol Bit 1 2:8 9 10 11:18 19 20:27 28 29:36 37 38:45 46 Start Slave address – 7 bits Write = 0 Acknowledge from slave Command Code – 8 bits '00000000' stands for block operation Acknowledge from slave Byte Count – 8 bits Acknowledge from slave Data byte 1 – 8 bits Acknowledge from slave Data byte 2 – 8 bits Acknowledge from slave Description Bit 1 2:8 9 10 11:18 19 20 21:27 28 29 30:37 38 Start Slave address – 7 bits Write = 0 Acknowledge from slave Command Code – 8 bits '00000000' stands for block operation Acknowledge from slave Repeat start Slave address – 7 bits Read = 1 Acknowledge from slave Byte count from slave – 8 bits Acknowledge from master Block Read Protocol Description Rev 1.0, November 20, 2006 Page 3 of 16 CY28412 Table 3. Block Read and Block Write Protocol (continued) Block Write Protocol Bit .... .... .... .... .... .... ...................... Data Byte (N – 1) – 8 bits Acknowledge from slave Data Byte N – 8 bits Acknowledge from slave Stop Description Bit 39:46 47 48:55 56 .... .... .... Table 4. Byte Read and Byte Write Protocol Byte Write Protocol Bit 1 2:8 9 10 11:18 Start Slave address – 7 bits Write = 0 Acknowledge from slave Command Code – 8 bits '100xxxxx' stands for byte operation, bits[6:0] of the command code represents the offset of the byte to be accessed Acknowledge from slave Data byte from master – 8 bits Acknowledge from slave Stop Description Bit 1 2:8 9 10 11:18 Start Slave address – 7 bits Write = 0 Acknowledge from slave Command Code – 8 bits '100xxxxx' stands for byte operation, bits[6:0] of the command code represents the offset of the byte to be accessed Acknowledge from slave Repeat start Slave address – 7 bits Read = 1 Acknowledge from slave Data byte from slave – 8 bits Acknowledge from master Stop Byte Read Protocol Description Block Read Protocol Description Data byte from slave – 8 bits Acknowledge from master Data byte from slave – 8 bits Acknowledge from master Data byte N from slave – 8 bits Acknowledge from master Stop 19 20:27 28 29 19 20 21:27 28 29 30:37 38 39 Control Registers Byte 0:Control Register 0 Bit 7 6 5 4 3 2 1 0 @Pup 1 1 1 1 1 1 1 1 Name CPUT2_ITP/SRCT6 CPUC2_ITP/SRCC6 SRC[T/C]5 SRC[T/C]4 SRC[T/C]3 SATAT/C] SRC[T/C]2 SRC[T/C]1 SRC[T/C]0 Description CPU[T/C]2_ITP/SRC[T/C]6 Output Enable 0 = Disable (Hi-Z), 1 = Enable SRC[T/C]5 Output Enable 0 = Disable (Hi-Z), 1 = Enable SRC[T/C]4 Output Enable 0 = Disable (Hi-Z), 1 = Enable SRC[T/C]3 Output Enable 0 = Disable (Hi-Z), 1 = Enable SATA[T/C] Output Enable 0 = Disable (Hi-Z), 1 = Enable SRC[T/C]2 Output Enable 0 = Disable (Hi-Z), 1 = Enable SRC[T/C]1 Output Enable 0 = Disable (Hi-Z), 1 = Enable SRC[T/C]0 Output Enable 0 = Disable (Hi-Z), 1 = Enable Rev 1.0, November 20, 2006 Page 4 of 16 CY28412 Byte 1: Control Register 1 Bit 7 @Pup 1 Name CPUT/C SRCT/C PCIF PCI DOT_96T/C USB_48 REF0 REF1 CPU[T/C]1 CPU[T/C]0 CPUT/C SRCT/C PCIF PCI Description Center Spread Enable 0 = ±0.25% Center Spread, 1 = –0.5% Down Spread 6 5 4 3 2 1 0 1 1 1 1 1 1 0 DOT_96 MHz Output Enable 0 = Disable (Hi-Z), 1 = Enabled USB_48 MHz Output Enable 0 = Disabled, 1 = Enabled REF0 Output Enable 0 = Disabled, 1 = Enabled REF1 Output Enable 0 = Disabled, 1 = Enabled CPU[T/C]1 Output Enable 0 = Disable (Hi-Z), 1 = Enabled CPU[T/C]0 Output Enable 0 = Disable (Hi-Z), 1 = Enabled Spread Spectrum Enable 0 = Spread off, 1 = Spread on Byte 2: Control Register 2 Bit 7 6 5 4 3 2 1 0 @Pup 1 1 1 1 1 1 1 1 Name PCI5 PCI4 PCI3 PCI2 PCI1 PCI0 PCIF1 PCIF0 PCI5 Output Enable 0 = Disabled, 1 = Enabled PCI4 Output Enable 0 = Disabled, 1 = Enabled PCI3 Output Enable 0 = Disabled, 1 = Enabled PCI2 Output Enable 0 = Disabled, 1 = Enabled PCI1 Output Enable 0 = Disabled, 1 = Enabled PCI0 Output Enable 0 = Disabled, 1 = Enabled PCIF1 Output Enable 0 = Disabled, 1 = Enabled PCIF0 Output Enable 0 = Disabled, 1 = Enabled Description Byte 3: Control Register 3 Bit 7 6 5 4 3 @Pup 0 0 0 0 0 Name CPUT2_ITP/SRCT6 CPUC2_ITP/SRCC6 SRC[T/C]5 SRC[T/C]4 SRC[T/C]3 SATA[T/C] Description Allow control of SRC[T/C]6 with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Allow control of SRC[T/C]5with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Allow control of SRC[T/C]4 with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Allow control of SRC[T/C]3with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Allow control of SATA[T/C] with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Rev 1.0, November 20, 2006 Page 5 of 16 CY28412 Byte 3: Control Register 3 (continued) Bit 2 1 0 @Pup 0 0 0 Name SRC2 SRC1 SRC0 Description Allow control of SRC[T/C]2 with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Allow control of SRC[T/C]1 with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Allow control of SRC[T/C]0 with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Byte 4: Control Register 4 Bit 7 6 5 4 3 2 1 0 @Pup 0 0 0 0 0 1 1 1 Name RESERVED DOT96[T/C] PCIF1 PCIF0 RESERVED RESERVED RESERVED RESERVED RESERVED, Set = 0 DOT_PWRDWN Drive Mode 0 = Driven in PWRDWN, 1 = Hi-Z Allow control of PCIF2 with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# Allow control of PCIF1 with assertion of SW PCI_STP# 0 = Free-running, 1 = Stopped with SW PCI_STP# RESERVED, Set = 0 RESERVED, Set = 1 RESERVED, Set = 1 RESERVED, Set = 1 Description Byte 5: Control Register 5 Bit 7 @Pup 0 Name Description SRC[T/C][6:0],SATA[T/C] SRC[T/C], SATA[T/C]Stop Drive Mode 0 = Driven when SW PCI_STP# asserted,1 = Hi-Z when PCI_STP# asserted RESERVED RESERVED RESERVED RESERVED, Set = 0 RESERVED, Set = 0 RESERVED, Set = 0 6 5 4 3 2 1 0 0 0 0 0 0 0 0 SRC[T/C][6:0],SATA[T/C] SRC[T/C], SATA[T/C] PWRDWN Drive Mode 0 = Driven when PD asserted,1 = Hi-Z when PD asserted CPU[T/C]2 CPU[T/C]1 CPU[T/C]0 CPU[T/C]2 PWRDWN Drive Mode 0 = Driven when PD asserted,1 = Hi-Z when PD asserted CPU[T/C]1 PWRDWN Drive Mode 0 = Driven when PD asserted,1 = Hi-Z when PD asserted CPU[T/C]0 PWRDWN Drive Mode 0 = Driven when PD asserted,1 = Hi-Z when PD asserted Rev 1.0, November 20, 2006 Page 6 of 16 CY28412 Byte 6: Control Register 6 Bit 7 6 5 4 3 @Pup 0 0 1 1 1 REF1 REF0 PCIF, SRC, PCI Name RESERVED RESERVED, Set = 0 Test Clock Mode Entry Control 1 = Hi-Z mode, 0 = Normal operation REF1 Output Drive Strength 0 = Low, 1 = High REF0 Output Drive Strength 0 = Low, 1 = High SW PCI_STP# Function 0=SW PCI_STP assert, 1= SW PCI_STP deassert When this bit is set to 0, all STOPPABLE PCI, PCIF and SRC outputs will be stopped in a synchronous manner with no short pulses. When this bit is set to 1, all STOPPED PCI, PCIF and SRC outputs will resume in a synchronous manner with no short pulses. FS_C. Reflects the value of the FS_C pin sampled on power up 0 = FS_C was low during VTT_PWRGD# assertion FS_B. Reflects the value of the FS_B pin sampled on power up 0 = FS_B was low during VTT_PWRGD# assertion FS_A. Reflects the value of the FS_A pin sampled on power up 0 = FS_A was low during VTT_PWRGD# assertion Description 2 1 0 Externally selected Externally selected Externally selected CPUT/C CPUT/C CPUT/C Byte 7: Vendor ID Bit 7 6 5 4 3 2 1 0 @Pup 0 0 1 0 1 0 0 0 Name Revision Code Bit 3 Revision Code Bit 2 Revision Code Bit 1 Revision Code Bit 0 Vendor ID Bit 3 Vendor ID Bit 2 Vendor ID Bit 1 Vendor ID Bit 0 Revision Code Bit 3 Revision Code Bit 2 Revision Code Bit 1 Revision Code Bit 0 Vendor ID Bit 3 Vendor ID Bit 2 Vendor ID Bit 1 Vendor ID Bit 0 Description Crystal Recommendations The CY28412 requires a Parallel Resonance Crystal. Substituting a series resonance crystal will cause the CY28412 to operate at the wrong frequency and violate the ppm specification. For most applications there is a 300-ppm frequency shift between series and parallel crystals due to incorrect loading. Crystal Loading Crystal loading plays a critical role in achieving low ppm performance. To realize low ppm performance, the total capacitance the crystal will see must be considered to calculate the appropriate capacitive loading (CL). The following diagram shows a typical crystal configuration using the two trim capacitors. An important clarification for the following discussion is that the trim capacitors are in series with the crystal not parallel. It’s a common misconception that load capacitors are in parallel with the crystal and should be approximately equal to the load capacitance of the crystal. This is not true. Table 5. Crystal Recommendations Frequency (Fund) 14.31818 MHz Cut AT Loading Load Cap Parallel 20 pF Drive (max.) 0.1 mW Shunt Cap (max.) 5 pF Motional (max.) 0.016 pF Tolerance (max.) 50 ppm Stability (max.) 50 ppm Aging (max.) 5 ppm Rev 1.0, November 20, 2006 Page 7 of 16 CY28412 Figure 1. Crystal Capacitive Clarification Calculating Load Capacitors In addition to the standard external trim capacitors, trace capacitance and pin capacitance must also be considered to correctly calculate crystal loading. As mentioned previously, the capacitance on each side of the crystal is in series with the crystal. This means the total capacitance on each side of the crystal must be twice the specified crystal load capacitance (CL). While the capacitance on each side of the crystal is in series with the crystal, trim capacitors (Ce1,Ce2) should be calculated to provide equal capacitive loading on both sides. As mentioned previously, the capacitance on each side of the crystal is in series with the crystal. This mean the total capacitance on each side of the crystal must be 2 times the specified load capacitance (CL). While the capacitance on each side of the crystal is in series with the crystal, trim capacitors (Ce1,Ce2) should be calculated to provide equal capacitance loading on both sides. Use the following formulas to calculate the trim capacitor values for Ce1 and Ce2. Load Capacitance (each side) Ce = 2 * CL – (Cs + Ci) Total Capacitance (as seen by the crystal) CLe PD (Power-down) Clarification The VTT_PWRGD# /PD pin is a dual function pin. During initial power-up, the pin functions as VTT_PWRGD#. Once VTT_PWRGD# has been sampled low by the clock chip, the pin assumes PD functionality. The PD pin is an asynchronous active high input used to shut off all clocks cleanly prior to shutting off power to the device. This signal is synchronized internal to the device prior to powering down the clock synthesizer. PD is also an asynchronous input for powering up the system. When PD is asserted high, all clocks are driven to a low value and held prior to turning off the VCOs and the crystal oscillator. PD (Power-down) – Assertion When PD is sampled high by two consecutive rising edges of CPUC, all single-ended outputs will be held low on their next high to low transition and differential clocks must be held high or Hi-Z (depending on the state of the control register drive mode bit) on the next diff clock# high to low transition. When the SMBus PD drive mode bit corresponding to the differential (CPU, SRC, and DOT) clock output of interest is programmed to ‘0’, the clock output must be held with “Diff clock” pin driven high at 2 x Iref, and “Diff clock#” tristate. If the control register PD drive mode bit corresponding to the output of interest is programmed to “1”, then both the “Diff clock” and the “Diff clock#” are Hi-Z. Note the example below shows CPUT = 133 MHz and PD drive mode = ‘1’ for all differential outputs. This diagram and description is applicable to valid CPU frequencies 100,133,166,200,266,333, and 400 MHz. In the event that PD mode is desired as the initial power-on state, PD must be asserted high in less than 10 s after asserting VTT_PWRGD#. = 1 ( Ce1 + Cs1 + Ci1 + 1 1 Ce2 + Cs2 + Ci2 ) CL ................................................... Crystal load capacitance CLe .........................................Actual loading seen by crystal using standard value trim capacitors Ce .....................................................External trim capacitors Cs ............................................. Stray capacitance (terraced) Ci .......................................................... Internal capacitance (lead frame, bond wires etc.) Rev 1.0, November 20, 2006 Page 8 of 16 CY28412 clock chip. All differential outputs stopped in a tristate condition resulting from power down must be driven high in less than 300 s of PD deassertion to a voltage greater than 200 mV. After the clock chip’s internal PLL is powered up and locked, all outputs are enabled within a few clock cycles of each other. PD Deassertion The power-up latency is less than 1.8 ms. This is the time from the deassertion of the PD pin or the ramping of the power supply until the time that stable clocks are output from the Clock Chip Ci1 Ci2 Pin 3 to 6p Cs1 X1 X2 Cs2 Trace 2.8pF XTAL Ce1 Ce2 Trim 33pF Figure 2. Crystal Loading Example PD CPUT, 133MHz CPUC, 133MHz SRCT 100MHz SRCC 100MHz USB, 48MHz DOT96T DOT96C PCI, 33 MHz REF Figure 3. Power-down Assertion Timing Waveform Rev 1.0, November 20, 2006 Page 9 of 16 CY28412 Below is an example showing the relationship of clocks coming up. Tstable 0.25m S VDD _A = 2.0V S am ple Inputs straps W ait for