CY28331 Clock Generator for AMD™ Hammer Features Table 1. Frequency Table (MHz)[1] • Supports AMD™ Hammer CPU • Two differential pairs of CPU clocks FS (3:0) PCI_HT SEL • Eight low-skew/low-jitter PCI clocks 0000 X • Four low-skew/low-jitter PCI/HyperTransport™ clocks 0001 0/1 133.9 67.0/33.5 33.5 • One 48M output for USB 0010 0/1 166.9 66.8/33.4 33.4 • One free-running PCI clock CPU HT66 PCI High-Z (All outputs except XOUT are three-stated) • One programmable 24M or 48M for FDC 0011 0/1 200.9 67.0/33.5 33.5 • Three REF 14.318 MHz clocks 0100 0/1 100.0 66.7/33.3 33.3 • Dial-a-Frequency£ programmability 0101 0/1 133.3 66.7/33.3 33.3 • Lexmark Spread Spectrum for optimal electromagnetic interference (EMI) reduction 0110 0/1 166.7 66.7/33.3 33.3 0111 (default) 0/1 200.0 66.7/33.3 33.3 • 5V-tolerance SCLK and SDATA lines 1000 0/1 105.0 70.0/35.0 35.0 • 3.3V operation 1001 0/1 110.0 73.3/36.7 36.7 • Power management control pins 1010 0/1 210.0 70.0/35.0 35.0 • 48-pin SSOP package 1011 0/1 240.0 60.0/30.0 30.0 1100 0/1 270.0 67.5/33.8 33.8 1101 0/1 233.3 58.3/29.2 29.2 • SMBus register-programmable options 1110 0/1 266.7 66.7/33.3 33.3 1111 0/1 300.0 75.0/37.5 37.5 Block Diagram XIN XOUT Pin Configuration 14.31818MHz XTAL REF(0:2) USB /4 PLL1 24_48MHz /2 SRESET# FS(0:3) CPUT(0:1) PLL2 CPUC(0:1) PCISTOP# SPREAD PD# Control Logic /N PCI33_F 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 CY28331 SEL# *FS0/REF0 VDD XIN XOUT VSS PCI33HT66_0/*PCI33HT66SEL0# PCI33HT66_1/*PCI33HT66SEL1# PCI33_HT66_2 VDD VSS PCI33_HT66_3 PCI33_7 PCI33_0 PCI33_1 VSS VDD PCI33_2 PCI33_3 VDD VSS PCI33_4 PCI33_5 PCISel/PCI33_F *PCI33_6/PCISTOP# 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 *FS1/REF1 VSS VDD *FS2/REF2 SRESET#/PD# VDDA VSSA CPUT0 CPUC0 VSS VDD CPUT1 CPUC1 VDD VSS VSSF VDDF **USB/FS3 VSS VDD 24_48MHz/**SEL# VSS SDATA SCLK SCLK SDATA STOP PCI33_(0:7) CNTL PCI33_HT66_(0:3) *100K Internal Pull-up **100K Internal Pull-down Note: 1. HCLK, 66 MHz, and 33 MHz are in phase and synchronous at power-up. Rev 1.0, November 24, 2006 2200 Laurelwood Road, Santa Clara, CA 95054 Page 1 of 16 Tel:(408) 855-0555 Fax:(408) 855-0550 www.SpectraLinear.com CY28331 Pin Description Pin Name PWR I/O Description 3 XIN VDD I Oscillator Buffer Input. Connect to a crystal or to an external clock. 4 XOUT VDD O Oscillator Buffer Output. Connect to a crystal. Do not connect when an external clock is applied at XIN. 41, 37 CPUT(0:1) VDDC O CPU clock outputs 0 and 1: push-pull “true” output of differential pair. 40, 36 CPUC(0:1) VDDC O CPU clock outputs 0 and 1: push-pull “complement” output of differential pair. 13, 14, 17, PCI33(0:5) 18, 21, 22 O 3.3V PCI clock outputs controlled by PCISTOP#. 23 PCISel / PCI33_F I/O PCISel is a strap option during power-up to select Pin 24 functionality: 0: Configure Pin 24 as PCI33_6 1: Configure Pin 24 as PCISTOP# (default 100k internal pull-up) After power-up, this pin reverts to standard PCI33_F output. 8, 11 PCI33_HT66(2:3) VDDD O 3.3V PCI 33 MHz or HyperTransport66 clock outputs. This group is selectable between 33 MHz and 66 MHz, based on the state of PCI33HT66SEL[0:1]#. 6, 7 PCI33_HT66_[0:1]/ PCI33_HT66SEL[0:1]# VDDD I/O PCI33 or HT66 select. This input strap selects the output frequency of PCI33_HT66 outputs to either 33 MHz or 66 MHz. There is an internal 100Kohm pull-up resistor. After power-up, this pin becomes PCI33_HT66_[0:1] output. SEL1 SEL0 PIN6 PIN7 PIN8 PIN11 0 0 HT66_0 HT66_1 HT66_2 HT66_3 0 1 HT66_0 HT66_1 HT66_2 PCI33_3 1 0 HT66_0 HT66_1 PCI33_2 PCI33_3 1 1 HT66_0 PCI33_1 PCI33_2 PCI33_3 31 USB/FS3 I/O 3.3V USB clock output at 48 MHz. At power-up this pin is sensed to determine the CPU output frequency. There is an internal 100K-ohm pull-down resistor. 28 24_48MHz/SEL# I/O 3.3V super I/O clock output. At power-up this pin is sensed to determine whether the output is 24 MHz or 48 MHz. There is an internal 100K-ohm pull-down resistor. This pin will be externally strapped high using a 10K-ohm resistor to VSS. 0 = 48 MHz, 1 = 24 MHz. 1, 48, 45 REF(0:2)/FS(0:2) I/O 3.3V reference clock output. At power-up this pin is sensed to determine the CPU output frequency. There is an internal 100K-ohm pull-up resistor for FS0, while FS(1:2) includes 100K ohm pull-up resistors. 44 SRESET#/PD# I/O Watchdog Time-out Reset Output. Power-down input (100K internal pull-up). 24 PCI33_6/ PCISTOP# I/O When configured through pin 23 as PCI_STOP#, this pin controls the PCI33(0:5,7) and PCI33_HT66(1:3) outputs. Active LOW control input to halt all 33-MHz PCI clocks except PCI33_F. Only the PCI33_HT66 outputs that are running at 33 MHz will be stopped. The outputs will be glitch-free when turning off and turning on (100K internal pull-up). When configured through pin 23 as PCI33_6, PCI_STOP# is unavailable. 12 PCI33_7 O 3.3V PCI clock outputs controlled by PCISTOP#. 26 SDATA I/O Data pin for SMBus (rev2.0). There is an internal 100K-ohm pull-up resistor. 25 SCLK I Clock pin for SMBus (rev2.0). There is an internal 100K-ohm pull-up resistor. VDD 2, 9, 16, 19, 29, 35, 38, 46 PWR Power connection to 3.3V for the core. 5, 10, 15, VSS 20, 27, 30, 34, 39, 47 GND Power connection to GROUND for the CORE section of the chip. Rev 1.0, November 24, 2006 Page 2 of 16 CY28331 Pin Description (continued) Pin Name PWR I/O Description 43 VDDA 42 VSSA GND Power connection to GROUND for the analog section of the chip. 32 VDDF PWR Power connection to 3.3V for the 48 MHz PLL section of the chip. 33 VSSF GND Power connection to GROUND for the 48 MHz PLL section of the chip. PWR Power connection to 3.3V for the ANALOG section of the chip. Serial Data Interface Data Protocol To enhance the flexibility and function of the clock synthesizer, a two-signal serial interface is provided. Through the Serial Data Interface (SDI), various device functions, such as individual clock output buffers, can be individually enabled or disabled. The registers associated with the SDI initialize 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 can also be used during system operation for power management functions. 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). Table 2. Command Code Definition Bit Description 7 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 Description Start Slave address – 7 bits Block Read Protocol Bit 1 2:8 Description Start Slave address – 7 bits 9 Write = 0 9 Write = 0 10 Acknowledge from slave 10 Acknowledge from slave 11:18 19 20:27 28 29:36 37 38:45 Command Code – 8 bits '00000000' stands for block operation 11:18 Command Code – 8 bits '00000000' stands for block operation Acknowledge from slave 19 Acknowledge from slave Byte Count – 8 bits 20 Repeat start Acknowledge from slave Data byte 1 – 8 bits Acknowledge from slave Data byte 2 – 8 bits 21:27 Slave address – 7 bits 28 Read = 1 29 Acknowledge from slave 30:37 46 Acknowledge from slave .... ...................... .... Data Byte (N–1) – 8 bits 47 .... Acknowledge from slave 48:55 .... Data Byte N – 8 bits 56 Acknowledge .... Acknowledge from slave .... Data bytes from slave/Acknowledge .... Stop .... Data byte N from slave – 8 bits .... Not Acknowledge .... Stop Rev 1.0, November 24, 2006 38 Byte count from slave – 8 bits 39:46 Acknowledge Data byte from slave – 8 bits Acknowledge Data byte from slave – 8 bits Page 3 of 16 CY28331 Table 4. Byte Read and Byte Write Protocol Byte Write Protocol Bit Byte Read Protocol Description 1 Bit Start 2:8 1 Slave address – 7 bits 2:8 Description Start Slave address – 7 bits 9 Write = 0 9 Write = 0 10 Acknowledge from slave 10 Acknowledge from slave 11:18 19 20:27 Command Code – 8 bits '1xxxxxxx' stands for byte operation, bits[6:0] of the command code represents the offset of the byte to be accessed 11:18 Command Code – 8 bits '1xxxxxxx' stands for byte operation, bits[6:0] of the command code represents the offset of the byte to be accessed Acknowledge from slave 19 Acknowledge from slave Data byte from master – 8 bits 20 Repeat start 28 Acknowledge from slave 29 Stop 21:27 28 29 30:37 Slave address – 7 bits Read = 1 Acknowledge from slave Data byte from slave – 8 bits 38 Not Acknowledge 39 Stop Serial Control Registers Byte 0: Frequency and Spread Spectrum Control Register Bit @Pup 7 Inactive = 0 Pin# Name 6 0 5 1 12 PCI33_7 Description Write Disable (write once). A 1 written to this bit after a 1 has been written to Byte0 bit0 will permanently disable modification of all configuration registers until the part has been powered off. Once the clock generator has been Write Disabled, the SMBus controller should still accept and acknowledge subsequent write cycles but it should not modify any of the registers. For Test, always program to ‘0’ Enable (1 = Enabled, 0 = Disabled) 4 FS3 pin 31 FS3 corresponds to Frequency Selection. See Table 1. 3 FS2 pin 45 FS2 corresponds to Frequency Selection. See Table 1. 2 FS1 pin 48 FS1 corresponds to Frequency Selection. See Table 1. 1 FS0 pin 1 FS0 corresponds to Frequency Selection. See Table 1. 0 Inactive = 0 Write Enable. A 1 written to this bit after power-up will enable modification of all configuration registers and subsequent 0's written to this bit will disable modification of all configuration except this single bit. Note that block write transactions to the interface will complete, however unless the interface has been previously unlocked, the writes will have no effect. The effect of writing this bit doe not take effect until the subsequent block write command. Byte 1: PCI Clock Control Register Bit @Pup Pin# Name 7 1 23 PCI33_F Enable (1 = Enabled, 0 = Disabled) 6 1 24 PCI33_6 Enable (1 = Enabled, 0 = Disabled) 5 1 22 PCI33_5 Enable (1 = Enabled, 0 = Disabled) 4 1 21 PCI33_4 Enable (1 = Enabled, 0 = Disabled) 3 1 18 PCI33_3 Enable (1 = Enabled, 0 = Disabled) 2 1 17 PCI33_2 Enable (1 = Enabled, 0 = Disabled) 1 1 14 PCI33_1 Enable (1 = Enabled, 0 = Disabled) Rev 1.0, November 24, 2006 Description Page 4 of 16 CY28331 Byte 1: PCI Clock Control Register (continued) Bit @Pup Pin# Name 0 1 13 PCI33_0 Description Enable (1 = Enabled, 0 = Disabled) Byte 2: USB, 24–48MHz, REF(0:2) Control Register Bit @Pup Pin # 7 active = 1 37, 36 CPUT/C(1) CPUT/C(1) shutdown. This bit can be optionally used to disable the CPUT/C(1) clock pair. During shutdown, CPUT = low and CPUC = high Name Description 6 active = 1 41, 40 CPUT/C(0) CPUT/C(0) shutdown. This bit can be optionally used to disable the CPUT/C(0) clock pair. During shutdown, CPUT = low and CPUC = high 5 active = 1 45 REF2 Enable (1 = Enabled, 0 = Disabled) 4 active = 1 48 REF1 Enable (1 = Enabled, 0 = Disabled) 3 active = 1 1 REF0 Enable (1 = Enabled, 0 = Disabled) 2 active = 1 28 1 active = 1 31 0 0 24_48MHz Enable (1 = Enabled, 0 = Disabled) USB Enable (1 = Enabled, 0 = Disabled) For Test, always program to ‘0’ Byte 3: PCI Clock Free Running Select Control Register Bit @Pup Pin # Name Description 7 Inactive = 0 PCI_DRV 0 = Low Strength 1 = High Strength 6 Inactive = 0 PCI33_HT66 Drive Strength 0 = Low Strength 1 = High Strength 5 Inactive = 0 22 PCI5 Free running enable (10 = Free running, 0 = Disabled) 4 Inactive = 0 21 PCI4 Free running enable (1 = Free running, 0 = Disabled) 3 Inactive = 0 18 PCI3 Free running enable (1 = Free running, 0 = Disabled) 2 1 11 PCI33_HT66_3 Enable (1 = Enabled, 0 = Disabled) 1 1 8 PCI33_HT66_2 Enable (1 = Enabled, 0 = Disabled) 0 1 7 PCI33_HT66_1 Enable (1 = Enabled, 0 = Disabled) Byte 4: Pin Latched/Real-time State Bit @Pup Pin# Name 7 1 6 6 HW 5 0 Reserved 4 1 SSEN 3 FS3 pin 31 FS3 Power-up latched state 2 FS2 pin 45 FS2 Power-up latched state 1 FS1 pin 48 FS1 Power-up latched state 0 FS0 pin 1 FS0 Power-up latched state PCI33_HT66_0 Description Enable (1 = Enabled, 0 = Disabled) 24_48MHz/SEL# Pin power-up latched state Rev 1.0, November 24, 2006 For Test, always program to ‘0’ Spread Spectrum enable (0 = disable, 1 = enable). This bit provides a SW programmable control for spread spectrum clocking. Page 5 of 16 CY28331 Byte 5: SSCG, Dial-a-Skew™, and Dial-a-Ratio™ Register Bit @Pup 7 0 6 1 5 1 4 0 3 0 2 0 1 0 0 0 Description Spread Spectrum Selection: bit7 bit6 bit5 % Spread 0 0 0 –1.5 0 0 1 –1.0 0 1 0 –0.7 0 1 1 –0.5 (default) 1 0 0 ±0.75 1 0 1 ±0.50 1 1 0 ±0.35 1 1 1 ±0.25 HT66 Frequency Fractional Aligner: These bits determine the HT66 fixed frequency when the HT66 Output Frequency Selection bit is set. It does not incorporate spread spectrum. Fract_Align PCI_HT PCI bit[4:0] (MHz) (MHz) 00000 Off Off (default) 00001 66.5 33.2 00010 67.5 33.7 00011 68.5 34.3 00100 69.5 34.8 00101 70.6 35.3 00110 71.6 35.8 00111 72.6 36.3 01000 73.6 36.8 01001 74.7 37.3 01010 75.7 37.8 01011 76.7 38.4 01100 77.7 38.9 01101 78.7 39.4 01110 79.8 39.9 01111 80.8 40.4 10000 81.8 40.9 10001 82.8 41.4 10010 83.9 41.9 10011 84.9 42.4 10100 85.9 43.0 10101 86.9 43.5 10110 88.0 44.0 10111 89.0 44.5 11000 90.0 45.0 11001 91.0 45.5 11010 92.0 46.0 11011 93.1 46.5 11100 94.1 47.0 11101 95.1 47.6 11110 96.1 48.1 11111 97.2 48.6 Byte 6: Watchdog Control Register Bit @Pup 7 0 6 0 Name Description HT66 Output Frequency HT66 Output Frequency Selection: Selection 0: Set according to Frequency Selection Table 1: Set according to Fractional Aligner Table Pin 44 Mode Select Rev 1.0, November 24, 2006 Pin 44 Mode Select: 0 = Pin 12 is the output pin as SRESET# signal. 1 = Pin 12 is the input pin which functions as a PD# signal. Page 6 of 16 CY28331 Byte 6: Watchdog Control Register (continued) Bit @Pup Name Description 5 0 Frequency Reversion Frequency Reversion: This bit allows setting the Revert Frequency once the system is rebooted due to Watchdog time out only. 0 = Selects frequency of existing H/W setting 1 = Selects frequency of the second to last S/W setting. (the software setting prior to the one that caused a system reboot). 4 0 WD Time-out WD Time-out: This bit is set to “1” when the Watchdog times out. It is reset to “0” when the system clears the WD time stamps (WD3:0). 3 0 WD3 2 0 WD2 1 0 WD1 0 0 WD0 This bit allows the selection of the time stamp for the Watchdog timer. After a Watchdog time-out, the frequency will revert to the original frequency. WD3 .. .. WD0 0 0 0 0 Off (default) 0 0 0 1 1 second 0 0 1 0 2 seconds 0 0 1 1 3 seconds 0 1 0 0 4 seconds 0 1 0 1 5 seconds 0 1 1 0 6 seconds 0 1 1 1 7 seconds 1 0 0 0 8 seconds 1 0 0 1 9 seconds 1 0 1 0 10 seconds 1 0 1 1 11 seconds 1 1 0 0 12 seconds 1 1 0 1 13 seconds 1 1 1 0 14 seconds 1 1 1 1 15 seconds Byte 7: Clock Vendor ID Bit @Pup Description 7 0 Revision ID[1] 6 1 Revision ID[0] 5 0 Device ID[9] 4 1 Device ID[8] 3 1 Vendor ID[3] 2 0 Vendor ID[2] 1 0 Vendor ID[1] 0 0 Vendor ID[0] Byte 8: Device ID Bit @Pup 7 0 Device ID 6 1 Device ID 5 0 Device ID 4 0 Device ID 3 1 Device ID 2 0 Device ID 1 1 Device ID 0 1 Device ID Rev 1.0, November 24, 2006 Description Page 7 of 16 CY28331 Byte 9: Dial-a-Frequency Control Register N Bit @PUp 7 0 6 N6 5 N5 4 N4 3 N3 2 N2 1 N1 0 N0 Description ATPG Pulse These bits are for programming the PLL’s internal N register. This access allows the user to modify the CPU frequency with great accuracy. All other synchronous clocks (clocks that are generated from the same PLL, such as PCI, remain at their existing ratios relative to the CPU clock. Byte 10: Dial-a-Frequency Control Register M Bit @Pup 7 0 6 M5 5 M4 4 M3 3 M2 2 M1 1 M0 0 DAFEN Description ATPG Mode (default = 0) These bits are for programming the PLL’s internal M register. This access allows the user to modify the CPU frequency with great accuracy. All other synchronous clocks (clocks that are generated from the same PLL, such as PCI, remain at their existing ratios relative to the CPU clock. When this bit = 1, it enables the Dial-a-Frequency N and M bits to be multiplexed into the internal N and M registers. When this bit = 0, the ROM based N and M values are loading into the internal N and M registers. Byte 11: Bit @Pup 7 0 Pin # Name Description For Test, ALWAYS program to ‘0’ HW 7 5 HW 6 4 0 Reserved Set = 0 3 0 Reserved Set = 0 2 0 Reserved Set = 0 1 0 Reserved Set = 0 0 0 Reserved Set = 0 6 PCI33HT66SEL1# PCI33/HT66 Mode Select 1 Power-up Latched State of PCI33HT66SEL1# Mode Select 1 (read only). PCI33HT66SEL0# PCI33/HT66 Mode Select 0 Power-up Latched State of PCI33HT66SEL0# Mode Select 0 (read only). System Self-Recovery Clock Management This feature is designed to allow the system designer to change frequency while the system is running and reboot the operation of the system in case of a hang up due to the frequency change. When the system sends an SMBus command requesting a frequency change through the Dial-a-Frequency Control Registers, it must have previously sent a command to the Watchdog Timer to select which time out stamp the Watchdog must perform, otherwise the System Self-Recovery feature will not be applicable. Consequently, this device will change frequency and then the Watchdog timer starts timing. Meanwhile, the system BIOS is running its operation with the Rev 1.0, November 24, 2006 new frequency. If this device receives a new SMBus command to clear the bits originally programmed in Watchdog Timer bits (reprogram to 0000) before the Watchdog times out, then this device will keep operating in its normal condition with the new selected frequency. The Watchdog timer will also be triggered if you program the software frequency select bits (FSEL) to a new frequency selection. If the Watchdog times out before the new SMBus reprograms the Watchdog Timer bits to (0000), then this device will send a low system reset pulse, on SRESET#, and changes WD Time-out bit to “1.” Page 8 of 16 CY28331 RESET W ATCHDOG TIMER Set WD(0:3) Bits = 0 INITIALIZE W ATCHDOG TIMER Set Frequency Revert Bit Set WD(0:3) = (# of Sec ) x 2 SET SOFTW ARE FSEL Set SW Freq_Sel = 1 Set FS(0:4) SET DIAL-A-FREQUENCY Load M and N Registers Set Pro_Freq_EN = 1 Wait for 6msec For Clock Output to Ramp to Target Frequency N Hang? CLEAR W D Set WD(0:3) Bits = 0 Exit Y W ATCHDOG TIMEOUT Frequency Revert Bit = 0 Set Frequency to FS_HW_Latched Frequency Revert Bit = 1 Set Frequency to FS_SW Set SRESET# = 0 for 6 msec Reset Figure 1. Watchdog Flow Chart Rev 1.0, November 24, 2006 Page 9 of 16 CY28331 Dial-a-Frequency ROM M Register SMBus Control Register N Latch Control Register N White N Register SMBus Control Register M Control Register M White DAFEN Figure 2. Dial-a-Frequency Feature The SMBus controlled Dial-a-Frequency feature is available in this device via Dial-a-Frequency Control Register N and Dial-a-Frequency Control Register M. P is a PLL constant that depends on the frequency selection prior to accessing the Dial-a-Frequency feature. Table 5. FS(3:0) P 0000 0001 127994667 0010 191992000 0011 191992000 0100 95996000 0101 127994667 0110 191992000 0111 191992000 1000 95966000 1001 95966000 1010 191992000 1011 191992000 1100 191992000 1101 191992000 1110 191992000 1111 191992000 Operation Pin strapping on any configuration pin is based on a 10K ohm resistor connected to either 3.3V (VDD) or ground (VSS). When the VDD supply goes above 2.0V, the Power-on-Reset circuitry latches all of the configuration bits into their respective registers and then allows the outputs to be enabled. The output may not occur immediately after this time as the PLL needs to be locked and will not output an invalid frequency. The CPU frequencies are defined from the hardware-sampled inputs. Additional frequencies and operating states can be selected through the SMBus-programmable interface. Spread spectrum modulation is required for all outputs derived from the internal CPU PLL2. This include the CPU(0:1), PCI33(0:6), PCI33_F, and PCI33_HT66(0:3). The REF (0:2), USB, and 24_48 clocks are not affected by the spread spectrum modulation. The spread spectrum modulation is set for both center and down modes using a Lexmark profiles for amounts of 0.5% and 1.0% at a 33-KHz rate. The CPU clock driver is of a push-pull type for the differential outputs, instead of the Athlon open-drain style. The CPU clock termination has been derived such that a 15-40 ohm, 3.3V output driver can be used for the CPU clock. The PCISTOP# signal provides for synchronous control over the any output, except the PCI33_F, that is running at 33 MHz. If the PCI33_HT66 outputs are configured to run at 66 MHz will not be stopped by this signal. The PCISTOP# signal is sampled by an internal PCI clock such that once it is sensed low or active, the 33-MHz signals are stopped on the next high to low transition and remains low. The algorithm is the same for all P values, which is Fcpu = (P*N)/M with the following conditions. M = (20..58), N = (21..125) and N > M > N/2. Rev 1.0, November 24, 2006 Page 10 of 16 CY28331 Absolute Maximum Ratings Parameter Description Conditions Min. Max. Unit VDD, VDDA, VDDF Supply Voltage Non-functional –0.5 4.6 V VIN Input Voltage Functional –0.5 VDD + 0.5 V –65 +150 °C +150 °C TS Storage Temperature Non-functional TJ Temperature, Junction Functional ØJC Dissipation, Junction to Case Mil-Spec 883E Method 1012.1 32.78 °C/W ØJA Dissipation, Junction to Ambient JEDEC (JESD 51) 73.61 °C/W ESDh ESD Protection (Human Body Model) MIL-STD-883, Method 3015 Ul-94 Flammability Rating V–0 @1/8 in. MSL Moisture Sensitivity Level > 2,000 V 10 ppm 1 Recommended Operating Conditions Parameter Description Min. Typ. Max. Unit 3.135 3.3 3.465 V 70 qC VDD, VDDA, VDDF Supply Voltage TA Operating Temperature, Ambient 0 FXIN Input Frequency (Crystal or Reference) 10 14.318 16 MHz Min. Typ. SCLK and SDATA Input Electrical Characteristics (5V-tolerant) Parameter Description VIL Input Low Voltage Conditions VIH Input High Voltage IIL, IIH Input High/Low Current 0 < VIN < VDD VOL Output High Voltage IOL = 1.75 mA IOL Output Low Current VO = 0.8V Max. Unit VSS – 0.5 0.8 V 2.0 VDD + 0.3 V ±5 µA VSS – 0.3 0.4 V 2 6 mA DC Electrical Specifications (All outputs loaded) Parameter Description VIL Input Low Voltage Conditions VIH Input High Voltage IIL Input Low Current @VIL = VSS, except PU and PD IIH Input High Current @VIH = VDD, except PU and PD LTSL Three-state Leakage Current IDD3.3V Dynamic Supply Current IPD3.3V Power-down Supply Current CIN Input Pin Capacitance COUT Output Pin Capacitance LPIN Pin Inductance CXTAL Crystal Pin Capacitance VBIAS Crystal DC Bias Voltage Rev 1.0, November 24, 2006 Max. Unit VSS – 0.5 Min. 0.8 V 2.0 VDD + 0.5 V –5 µA CPU(0:1) @ 200 MHz Typ. µA µA 250 Except XIN and XOUT Measured from Pin to Ground. 5 10 mA 2 mA 5 pF 6 pF 7 nH 27 36 45 pF 0.3VDD VDD/2 0.7VDD V Page 11 of 16 CY28331 AC Electrical Specifications PCI133_HT66 = 66MHz Parameter Description Test Condition Min. Typ. Max. Unit Hammer CPU TR Output Rise Edge Rate Measured @ the Hammer test load using VOCM ± 400 mV, 0.850V to 1.650V 2 7 V/ns TF Output Fall Edge Rate Measured @ the Hammer test load using VOCM ± 400 mV, 1.650V to 0.850V 2 7 V/ns VDIFF Differential Voltage Measured @ the Hammer test load (single-ended) 0.4 2.3 V 'DIFF Change in VDIFF_DC Magnitude Measured @ the Hammer test load (single-ended) –150 150 mV VCM Common Mode Voltage Measured @ the Hammer test load (single-ended) 1.05 1.45 V 'VCM Change in VCM Measured @ the Hammer test load (single-ended) –200 200 mV 1.25 1.25 TDC Duty Cycle Measured at VOX 45 50 53 % TCYC Jitter, Cycle to Cycle Measured at VOX 0 100 200 ps TACCUM Jitter, Accumulated Measured at VOX –1000 1000 ps TFS Frequency Stabilization from Power-up Measure from full supply voltage 0 3 ms RON Output Impedance Average value during switching transition 15 55 W 0.4 V 35 PCI/HyperTransport Clock Outputs VOL Output Low Voltage IOL = 9.0 mA VOH Output High Voltage IOH = –12.0 mA 2.4 V IOL Output Low Current VO = 0.8V 10 mA IOH Output High Current VO = 2.0V F33 Frequency Actual –15 33.33 F66 mA MHz 66.67 MHz TR Output Rise Edge Rate Measured from 20% to 60% 0.5 4 V/ns TF Output Fall Edge Rate Measured from 60% to 20% TDC Duty Cycle Measured at 1.5V 0.5 4 V/ns 45 55 % TCCJ Cycle-to-Cycle Jitter Measured at 1.5V 0 400 ps TLTJ Long Term Jitter Measured at 1.5V –1000 1000 ps 0.4 V REF(0:2) Clock Outputs VOL Output Low Voltage IOL = 9.0 mA VOH Output High Voltage IOH = –12.0 mA 2.4 V IOL Output Low Current VO = 0.8V 16 mA IOH Output High Current VO = 2.0V F Frequency, Actual –22 14.318 mA MHz TR Output Rise Edge Rate Measured from 20% to 60% 0.5 2 V/ns TF Output Fall Edge Rate Measured from 60% to 20% 0.5 2 V/ns TDC Duty Cycle Measured at 1.5V 45 TCCJ Cycle-to-Cycle Jitter Measured at 1.5V 0 TLTJ Long-term Jitter Measured at 1.5V –1000 1000 ps TFS Frequency Stabilization from Power-up Measure from full supply voltage 0 3 mS Rev 1.0, November 24, 2006 500 55 % 1000 ps Page 12 of 16 CY28331 AC Electrical Specifications (continued) PCI133_HT66 = 66MHz Parameter RON Description Output Impedance Test Condition Min. Typ. Max. Unit Average value during switching transition 20 24 60 W USB, 24_48 Clock Outputs VOL Output Low Voltage IOL = 9.0 mA VOH Output High Voltage IOH = –12.0 mA 2.4 16 IOL Output Low Current VO = 0.8V IOH Output High Current VO = 2.0V F33 Frequency Actual 0.4 mA –22 F66 V V mA 24.004 MHz 48.008 MHz tR Output Rise Edge Rate Measured from 20% to 80% 0.5 2 V/ns tF Output Fall Edge Rate Measured from 80% to 20% 0.5 2 V/ns tD Duty Cycle Measured at 1.5V 45 TCCJ 24_48MHz Cycle-to-Cycle Jitter Measured at 1.5V 0 TCCJ USB Cycle-to-Cycle Jitter Measured at 1.5V 0 200 ps TLTJ Long-term Jitter Measured at 1.5V –1000 1000 ps TSTABLE Frequency Stabilization from Power-up Measure from full supply voltage 0 3 ms RON Output Impedance Average value during switching transition 20 60 W 250 24 55 % 500 ps Table 6. Skew [2] Parameter Description Conditions Skew Window Unit TSK_CPU_CPU CPU to CPU skew, time independent Measured @ crossing points for CPUT rising edges1 250 ps TSK_CPU_PCI33 CPU to PCI33 skew, time independent Measured @ crossing points for CPUT rising edge and 1.5V PCI clocks 500 ps TSK_PCI33_PCI33 PCI33 to PCI33 skew, time independent Measured between rising @ 1.5V 500 ps TSK_PCI33_HT66 PCI33 to HT66 skew, time independent Measured between rising @ 1.5V 500 ps TSK_CPU_HT66 CPU to HT66 skew, time independent Measured @ crossing points for CPUT rising edge and 1.5V for HyperTransport clocks 500 ps TSK_HT66_HT66 HT66 to HT66 skew, time independent Measured between rising @ 1.5V 500 ps TSK_CPU_CPU CPU to CPU skew, time variant Measured @ crossing points for CPUT rising edges 200 ps TSK_CPU_PCI33 CPU to PCI33 skew, time variant Measured @ crossing points for CPUT rising edge and 1.5V PCI clocks 200 ps TSK_PCI33_PCI33 PCI33 to PCI33 skew, time variant Measured between rising @ 1.5V 200 ps TSK_PCI33_HT66 PCI33 to HT66 skew, time variant Measured between rising @ 1.5V 200 ps TSK_CPU_HT66 CPU to HT66 skew, time variant Measured @ crossing points for CPUT rising edge and 1.5V for HyperTransport clocks 200 ps TSK_HT66_HT66 HT66 to HT66 skew, time variant Measured between rising @ 1.5V 200 ps Note: 2. All skews in this skew budget are measured from the first referenced signal to the next. Therefore, this skew specifies the maximum SKEW WINDOW between these two signals to be 500 ps whether the CPU crossing leads or lags the PCI clock. This should NOT be interpreted to mean that the PCI33 edge could either be 500 ps before the CPU clock to 500 ps after the clock, thus defining a 1000ps window in which the PCI33 clock edge could fall. Rev 1.0, November 24, 2006 Page 13 of 16 CY28331 Table 7. Max Load (in pF)[3] Clock Name CPU, USB, 24_48MHz, REF 20 PCI33, PCI33_F, PCI33_HT66 30 Tsu PCI_STP# PCI_F PCI Figure 3. PCISTOP# Assertion Waveform Tsu PCI_STP# PCI_F PCI Figure 4. PCISTOP# Deassertion Waveform Vbias=1.25V 125 ohms 15 ohms 125 ohms 3900pF 169 ohms 15 ohms 3900pF 5pF 5pF Figure 5. Test Load Configuration Note: 3. The above loads are positioned near each output pin when tested. Rev 1.0, November 24, 2006 Page 14 of 16 CY28331 SRESET#/PD# CPUT CPUC PCI/PCI_HT USB,24_48MHz REF Figure 6. PD# Assertion Waveform PD# CPUT CPUC PCI 33MHz 3V66 USB 48MHz REF 14.318MHz Figure 7. PD# Deassertion Waveform Ordering Information Part Number Package Type Product Flow CY28331OC 48-pin SSOP Commercial, 0q to 70qC CY28331OCT 48-pin SSOP – Tape and Reel Commercial, 0q to 70qC Lead-free CY28331OXC 48-pin SSOP Commercial, 0q to 70qC CY28331OXCT 48-pin SSOP – Tape and Reel Commercial, 0q to 70qC Rev 1.0, November 24, 2006 Page 15 of 16 CY28331 Package Drawing and Dimensions 48-pin Shrunk Small Outline Package O48 While SLI has reviewed all information herein for accuracy and reliability, Spectra Linear Inc. assumes no responsibility for the use of any circuitry or for the infringement of any patents or other rights of third parties which would result from each use. This product is intended for use in normal commercial applications and is not warranted nor is it intended for use in life support, critical medical instruments, or any other application requiring extended temperature range, high reliability, or any other extraordinary environmental requirements unless pursuant to additional processing by Spectra Linear Inc., and expressed written agreement by Spectra Linear Inc. Spectra Linear Inc. reserves the right to change any circuitry or specification without notice. Rev 1.0, November 24, 2006 Page 16 of 16