W254B 133-MHz Spread Spectrum FTG for Mobile Pentium® III Platforms Features APIC, 48-MHz, 3V66, PCI Outputs Cycle-to-Cycle Jitter: ...................................................500 ps • Maximized EMI suppression using Cypress’s Spread Spectrum technology (–0.5% and ±0.5%) • Single chip system FTG for Mobile Intel® Platforms • Two CPU outputs • Seven copies of PCI clock (one Free Running) • Seven SDRAM clock (one DCLK for Memory Hub) • Two copies of 48-MHz clock (non-spread spectrum) optimized for USB reference input and video DOT clock • Three 3V66 Hublink/AGP outputs • One VCH clock (48-MHz non-SSC or 66.67-MHz SSC) • One APIC outputs • One buffered reference output • Supports frequencies up to 133 MHz • SMBus interface for programming • Power management control inputs Key Specifications CPU Output Skew: ......................................................150 ps 3V66 Output Skew: .....................................................175 ps APIC, SDRAM Output Skew: ......................................250 ps PCI Output Skew:........................................................500 ps VDDQ3 (REF, PCI, 3V66, 48 MHz, SDRAM): ......... 3.3V±5% VDDQ2 (CPU, APIC):....... 2.5V±5%in Selectable Frequency Table 1. Pin Selectable Frequency Input Address FS1 FS0 0 0 0 1 1 0 1 1 Output Frequencies CPU SDRAM 48MHz PCI APIC REF 3V66 66 100 48 33 14.318 66 100 100 MHz MHz MHz MHz 133 133 133 100 CPU, SDRAM Outputs Cycle-to-Cycle Jitter:.............. 250 ps Block Diagram Pin Configuration XTAL OSC X1 X2 PLL 1 Divider Network VDD_REF PLL Ref Freq REF VDD_CPU CPU Stop Clock Control CPU_F CPU_STP# VDD_APIC APIC VDD_SDRAM DCLK VDD_PCI PCI_F/FS0 PWR_DWN# Stop Clock Control PCI1/FS1 PCI2:6 PCI_STP# VDD_3V66 3V66_0:1 3V66_AGP VDD_48 PLL2 USB (48MHz) 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 W254B SDRAM0:5 VDD_REF X1 X2 GND_REF GND_PCI PCI_F/FS0^ PCI1/FS1^ PCI2 VDD_PCI PCI3 PCI4 PCI5 PCI6 VDD_3V66 3V66_0 3V66_1 3V66_AGP GND_3V66 VCH_CLK GND_48 USB DOT VDD_48 GND_CORE 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 REF APIC VDD_APIC VDD_CPU CPU CPU_F GND_CPU GND_SDRAM SDRAM0 SDRAM1 VDD_SDRAM SDRAM2 SDRAM3 GND_SDRAM SDRAM4 SDRAM5 DCLK VDD_SDRAM CPU_STP# PCI_STP# PWR_DWN# SCLK SDATA VDD_CORE DOT (48MHz) SDATA SCLK SMBus Logic VCH_CLK Note: 1. Internal pull-down or pull-up resistors present on inputs marked with * or ^ respectively. Design should not rely solely on internal pull-up or pull-down resistor to set I/O pins HIGH or LOW respectively. Intel and Pentium are registered trademarks of Intel Corporation. Cypress Semiconductor Corporation Document #: 38-07233 Rev. *A • 3901 North First Street • San Jose • CA 95134 • 408-943-2600 Revised December 22, 2002 W254B Pin Definitions Pin No. Pin Type 44, 43 O CPU Clock Outputs: Frequency is set by the FS0:1 inputs or through serial input interface. The CPU output is gated by the CLK_STOP# input. 8, 10, 11, 12, 13, 6, 7 I/O 33-MHz PCI Outputs: Except for the PCI_F output, these outputs are gated by the PCI_STOP# input. Upon power up, FS0 and FS1 is configured momentarily as input latches allowing various output frequencies to be selected. See Table 2. 47 O APIC Output: 2.5V fixed 33.3-MHz clock. This output is synchronous to the CPU clock. SDRAM0:5, DCLK 40, 39, 37, 36, 34, 33, 32 O SDRAM Output Clocks: 3.3V outputs running at either 100 MHz or 133 MHz depending on the setting of FS0:1 inputs. DCLK is a free-running clock. 3V66_0:1, 3V66_AGP 15, 16, 17 O 66-MHz Clock Outputs: 3.3V fixed 66-MHz clock. USB 21 O USB Clock Output: 3.3V fixed 48-MHz, non-spread spectrum USB clock output. DOT 22 O Dot Clock Output: 3.3V fixed 48-MHz, non-spread spectrum signal. REF 48 O Reference Clock: 3.3V 14.318-MHz clock output. VCH_CLK 19 O Video Control Hub Clock Output: 3.3V selectable 48-MHz non-spread spectrum or 66.67-MHz spread spectrum clock output. PWR_DWN# 28 I Power-Down Control: 3.3V LVTTL-compatible input that places the device in power-down mode when held LOW. CPU_STP# 30 I CPU Output Control: 3.3V LVTTL-compatible input that stops only the CPU0 clock. Output remains in the LOW state. PCI_STP# 29 I PCI Output Control: 3.3V LVTTL-compatible input that stops PCI1:6 clocks. Output remains in the LOW state. SCLK 27 I SMBus Clock Input: Clock pin for SMBus circuitry. SDATA 26 I/O X1 2 I Crystal Connection or External Reference Frequency Input: This pin has dual functions. It can be used as an external 14.318-MHz crystal connection or as an external reference frequency input. X2 3 O Crystal Connection: Connection for an external 14.318-MHz crystal. If using an external reference, this pin must be left unconnected. 1, 9, 14, 23, 25, 31, 38 P 3.3V Power Connection: Power supply for core logic, PLL circuitry, SDRAM outputs buffers, PCI output buffers, reference output buffers and 48-MHz output buffers. Connect to 3.3V. 45, 46 P 2.5V Power Connection: Power for APIC and CPU output buffers. Connect to 2.5V. 4, 5, 18, 20, 24, 35, 41, 42 G Ground Connection: Connect all ground pins to the common system ground plane. Pin Name CPU CPU_F PCI1:6, PCI_F/FS0, PCI1/FS1 APIC VDD_REF, VDD_PCI, VDD _3V66, VDD_48, VDD_CORE, VDD_SDRAM, VDD_SDRAM VDD_APIC, VDD_CPU GND_REF, GND_PCI, GND_3V66, GND_48, GND_CORE GND_SDRAM, GND_SDRAM, GND_CPU Document #: 38-07233 Rev. *A Pin Description SMBus Data Input: Data pin for SMBus circuitry. Page 2 of 17 W254B VDD Output Strapping Resistor Series Termination Resistor 10 kΩ (Load Option 1) Clock Load W254B Output Buffer Power-on Reset Timer Hold Output Low Output Three-state Q 10 kΩ (Load Option 0) D Data Latch Figure 1. Input Logic Selection Through Resistor Load Option Overview ing clock outputs. The 2-ms timer starts when VDDQ3 reaches 2.0V. The input bits can only be reset by turning VDDQ3 off and then back on again. The W254B is a highly integrated frequency timing generator, supplying all the required clock sources for an Intel® architecture platform using graphics-integrated core logic. It should be noted that the strapping resistors have no significant effect on clock output signal integrity. The drive impedance of the clock output is 40Ω (nominal), which is minimally affected by the 10-kΩ strap to ground or VDDQ3. As with the series termination resistor, the output strapping resistor should be placed as close to the l/O pin as possible in order to keep the interconnecting trace short. The trace from the resistor to ground or VDDQ3 should be kept less than two inches in length to prevent system noise coupling during input logic sampling. Functional Description I/O Pin Operation Pins 6 and 7 are dual-purpose l/O pins. Upon power-up these pins act as logic inputs, allowing the determination of assigned device functions. A short time after power-up, the logic state of each pin is latched and the pins then become clock outputs. This feature reduces device pin count by combining clock outputs with input select pins. When the clock outputs are enabled following the 2-ms input period, target (normal) output frequency is delivered, assuming that VDDQ3 has stabilized. If VDDQ3 has not yet reached full value, output frequency initially may be below target but will increase to target once VDDQ3 voltage has stabilized. In either case, a short output clock cycle may be produced from the CPU clock outputs when the outputs are enabled. An external 10-kΩ “strapping” resistor is connected between each l/O pin and ground or VDDQ3. Connection to ground sets a latch to “0”, connection to VDDQ3 sets a latch to “1”. Figure 1 shows one suggested method for strapping resistor connection. Upon W254B power-up, the first 2 ms of operation is used for input logic selection. During this period, the PCI_F and PCI1 clock output buffers are three-stated, allowing the output strapping resistor on each l/O pin to pull the pin and its associated capacitive clock load to either a logic HIGH or logic LOW state. At the end of the 2-ms period, the established logic 0 or 1 condition of each l/O is pin is latched. Next the output buffers are enabled, converting all l/O pins into operat- CPU/ SDRAM Frequency Selection CPU output frequency is selected with I/O pins 6 and 7. For CPU/SDRAM frequency programming information refer to Table 2. Alternatively, frequency selections are available through the serial data interface. Table 2. Frequency Select Truth Table[2] Input Address FS1 FS0 0 0 Output Frequencies CPU SDRAM 0 66 100 1 100 100 1 0 133 133 1 1 133 100 [3] 48 MHz 48 MHz PCI APIC 33 MHz REF 3V66 14.318 MHz 66 MHz Notes: 2. Range of reference frequency allowed is min. = 14.316 MHz, nominal = 14.31818 MHz, max. = 14.32 MHz. 3. Frequency accuracy of 48 MHz must be +167 PPM to match USB default. Document #: 38-07233 Rev. *A Page 3 of 17 W254B Offsets Among Clock Signal Groups Figure 2 and Figure 3 represent the phase relationship among the different groups of clock outputs from W254B when it is providing a 66-MHz CPU clock and a 100-MHz CPU clock, 0 ns 10 ns 20 ns respectively. It should be noted that when CPU clock is operating at 100 MHz, CPU clock output is 180 degrees out of phase with SDRAM clock outputs. 30 ns 40 ns Cycle Repeats CPU 66-MHz SDRAM 100-MHz 3V66 66-MHz PCI 33-MHz APIC33-MHz REF 14.318-MHz USB 48-MHz DOT 48-MHz Figure 2. Group Offset Waveforms (66 Mhz CPU/100 MHz SDRAM Clock) Table 3. 66 MHz Group Timing Relationships and Tolerances CPU to SDRAM CPU to 3V66 SDRAM to 3V66 3V66 to PCI PCI to APIC USB & DOT Offset –2.5 ns 7.5 ns 0.0 ns 1.5-3.5 ns 0.0 ns Async Tolerance 500 ps 500 ps 500 ps 500 ps 1.0 ns N/A 0 ns 10 ns 20 ns 30 ns 40 ns Cycle Repeats CPU 100-MHz SDRAM 100-MHz 3V66 66-MHz PCI 33-MHz APIC33-MHz REF 14.318-MHz USB 48-MHz DOT 48-MHz Figure 3. Group Offset Waveforms (100 MHz CPU/100 MHz SDRAM Clock) Document #: 38-07233 Rev. *A Page 4 of 17 W254B Table 4. 100 MHz Group Timing Relationships and Tolerances CPU to SDRAM CPU to 3V66 SDRAM to 3V66 3V66 to PCI PCI to APIC USB & DOT Offset 5.0 ns 5.0ns 0.0 ns 1.5-3.5 ns 0.0 ns Async Tolerance 500 ps 500 ps 500 ps 500 ps 1.0 ns N/A 0 ns 10 ns 20 ns 30 ns 40 ns Cycle Repeats CPU 133-MHz SDRAM 100-MHz 3V66 66-MHz PCI 33-MHz APIC33-MHz REF 14.318-MHz USB 48-MHz DOT 48-MHz Figure 4. Group Offset Waveforms (133-MHz CPU/100-MHz SDRAM Clock) Table 5. 133 MHz/SDRAM 100 MHz Group Timing Relationships and Tolerances CPU to SDRAM CPU to 3V66 SDRAM to 3V66 3V66 to PCI PCI to APIC USB & DOT Offset 0.0 ns 0.0 ns 0.0 ns 1.5-3.5 ns 0.0 ns Async Tolerance 500 ps 500 ps 500 ps 500 ps 1.0 ns N/A 0 ns 10 ns 20 ns 30 ns 40 ns Cycle Repeats CPU 133-MHz SDRAM 133-MHz 3V66 66-MHz PCI 33-MHz APIC33-MHz REF 14.318-MHz USB 48-MHz DOT 48-MHz Figure 5. Group Offset Waveforms (133-MHz CPU/133-MHz SDRAM Clock) Document #: 38-07233 Rev. *A Page 5 of 17 W254B Table 6. 133 MHz/SDRAM Test Mode Group Timing Relationships and Tolerance CPU to SDRAM CPU to 3V66 SDRAM to 3V66 3V66 to PCI PCI to APIC USB& DOT Offset 3.75 ns 0.0 ns 3.75 ns 1.5-3.5 ns 0.0 ns Async Tolerance 500 ps 500 ps 500 ps 500 ps 1.0 ns N/A Power-Down Control W254B provides one PWR_DWN# signal to place the device in low-power mode. In low-power mode, the PLLs are turned off and all clock outputs are driven LOW. 0 ns 25 ns 50 ns 75 ns Center 1 2 VCO Internal CPU 100-MHz 3V66 66-MHz PCI 33 MHz APIC 33-MHz PwrDwn SDRAM 100-MHz REF 14.318-MHz USB 48-MHz Figure 6. W254B PWR_DWN# Timing Diagram[4, 5, 6, 7] Table 7. W254B Maximum Allowed Current Max. 2.5V supply consumption Max. discrete cap loads, VDDQ2 = 2.625V All static inputs = VDDQ3 or VSS Max. 3.3V supply consumption Max. discrete cap loads VDDQ3 = 3.465V All static inputs = VDDQ3 or VSS Powerdown Mode (PWR_DWN# = 0) < 1 mA < 1 mA Full Active 66 MHz FS1:0 = 00 (PWR_DWN# =1) 70 mA 280 mA Full Active 100 MHz FS1:0 = 01 (PWR_DWN# =1) 100 mA 280 mA Full Active 133 MHz FS1:0 = 11 (PWR_DWN# =1) 100 mA 280 mA W254B Condition Notes: 4. Once the PWR_DWN# signal is sampled LOW for two consecutive rising edges of CPU, clocks of interest will be held LOW on the next HIGH-to-LOW transition. 5. PWR_DWN# is an asynchronous input and metastable conditions could exist. This signal is synchronized inside W254B. 6. The shaded sections on the SDRAM, REF, and USB clocks indicate “Don’t Care” states. 7. Diagrams shown with respect to 100 MHz. Similar operation when CPU is 66 MHz. Document #: 38-07233 Rev. *A Page 6 of 17 W254B Spread Spectrum Frequency Timing Generation Where P is the percentage of deviation and F is the frequency in MHz where the reduction is measured. The output clock is modulated with a waveform depicted in Figure 8. This waveform, as discussed in “Spread Spectrum Clock Generation for the Reduction of Radiated Emissions” by Bush, Fessler, and Hardin, produces the maximum reduction in the amplitude of radiated electromagnetic emissions. The deviation selected for this chip is +0.5% or –0.5% of the selected frequency. Figure 8 details the Cypress spreading pattern. Cypress does offer options with more spread and greater EMI reduction. Contact your local Sales representative for details on these devices. The device generates a clock that is frequency modulated in order to increase the bandwidth that it occupies. By increasing the bandwidth of the fundamental and its harmonics, the amplitudes of the radiated electromagnetic emissions are reduced. This effect is depicted in Figure 7. As shown in Figure 7, a harmonic of a modulated clock has a much lower amplitude than that of an unmodulated signal. The reduction in amplitude is dependent on the harmonic number and the frequency deviation or spread. The equation for the reduction is: Spread Spectrum clocking is activated or deactivated by selecting the appropriate value for bit 3 in data byte 0 of the SMBus data stream. Refer to page 9 for more details. dB = 6.5 + 9*log10(P) + 9*log10(F) EMI Reduction Typical Clock Amplitude (dB) Amplitude (dB) SSFTG Spread Spectrum Enabled NonSpread Spectrum Frequency Span (MHz) Down Spread Frequency Span (MHz) Center Spread Figure 7. Clock Harmonic with and without SSCG Modulation Frequency Domain Representation 100% 90% 80% 70% 60% 50% 40% 30% 20% 10% 100% 90% 80% 70% 60% 50% 40% 30% 20% 10% FREQUENCY MAX. MIN. Figure 8. Typical Modulation Profile Document #: 38-07233 Rev. *A Page 7 of 17 W254B 1 bit 7 bits 1 1 8 bits 1 Start bit Slave Address R/W Ack Command Code Ack Ack Data Byte 1 Ack Data Byte 2 Ack 1 bit 8 bits 1 8 bits 1 ... Byte Count = N Data Byte N Ack Stop 8 bits 1 1 Figure 9. An Example of a Block Write[8] Serial Data Interface The W254B features a two-pin, serial data interface that can be used to configure internal register settings that control particular device functions. Data Protocol The clock driver serial protocol accepts only block writes from the controller. The bytes must be accessed in sequential order from lowest to highest byte with the ability to stop after any complete byte has been transferred. Indexed bytes are not allowed. A block write begins with a slave address and a write condition. After the command code the core logic issues a byte count which describes how many more bytes will follow in the message. If the host had 20 bytes to send, the first byte would be the number 20 (14h), followed by the 20 bytes of data. The byte count may not be 0. A block write command is allowed to transfer a maximum of 32 data bytes. The slave receiver address for W254B is 11010010. Figure 9 shows an example of a block write. The command code and the byte count bytes are required as the first two bytes of any transfer. W254B expects a command code of 0000 0000. The byte count byte is the number of additional bytes required for the transfer, not counting the command code and byte count bytes. Additionally, the byte count byte is required to be a minimum of 1 byte and a maximum of 32 bytes to satisfy the above requirement. Table 8 shows an example of a possible byte count value. A transfer is considered valid after the acknowledge bit corresponding to the byte count is read by the controller. The command code and byte count bytes are ignored by the W254B. However, these bytes must be included in the data write sequence to maintain proper byte allocation. Table 8. Example of Possible Byte Count Value Byte Count Byte Notes MSB LSB 0000 0000 Not allowed. Must have at least one byte 0000 0001 Data for functional and frequency select register (currently byte 0 in spec) 0000 0010 Writes first two bytes of data (byte 0 then byte 1) 0000 0011 Writes first three bytes (byte 0, 1, 2 in order) 0000 0100 Writes first four bytes (byte 0, 1, 2, 3 in order) 0000 0101 Writes first five bytes (byte 0, 1, 2, 3, 4 in order) 0000 0110 Writes first six bytes (byte 0, 1, 2, 3, 4, 5 in order) 0000 0111 Writes first seven bytes (byte 0, 1, 2, 3, 4, 5, 6 in order) 0010 0000 Max. byte count supported = 32 Note: 8. The acknowledgment bit is returned by the slave/receiver (W254B). Document #: 38-07233 Rev. *A Page 8 of 17 W254B W254B Serial Configuration Map 1. The serial bits will be read by the clock driver in the following order: Byte 0 - Bits 7, 6, 5, 4, 3, 2, 1, 0 2. All unused register bits (reserved and N/A) should be written to a “0” level. 3. All register bits labeled “Initialize to 0" must be written to zero during initialization. Failure to do so may result in higher than normal operating current. Byte 1 - Bits 7, 6, 5, 4, 3, 2, 1, 0 Byte N - Bits 7, 6, 5, 4, 3, 2, 1, 0 Byte 0: Control Register (1 = Enable, 0 = Disable)[9] Bit Pin# Name Pin Description Bit 7 19 VCH_CLK (Active/Inactive) Bit 6 -- Reserved Drive to ’0’ (Active/Inactive) Bit 5 43 CPU_F (Disabled/Enabled) Bit 4 44 CPU (Disabled/Enabled) Bit 3 -- Spread Spectrum (1 = On; 0 = Off) (Active/Inactive) Bit 2 22 DOT (48 MHz) (Disabled/Enabled) Bit 1 21 USB (48 MHz) (Disabled/Enabled) Bit 0 -- Reserved Drive to ’0’ (Active/Inactive) Byte 1: Control Register (1 = Enable, 0 = Disable)[9] Bit Bit 7 Pin# -- Name Reserved Drive to ’0’ Pin Description (Active/Inactive) Bit 6 -- Reserved Drive to ’0’ (Active/Inactive) Bit 5 33 SDRAM5 (Disabled/Enabled) Bit 4 34 SDRAM4 (Disabled/Enabled) Bit 3 36 SDRAM3 (Disabled/Enabled) Bit 2 37 SDRAM2 (Disabled/Enabled) Bit 1 39 SDRAM1 (Disabled/Enabled) Bit 0 40 SDRAM0 (Disabled/Enabled) Byte 2: Control Register (1 = Enable, 0 = Disable)[9] Bit Pin# Name Pin Description Bit 7 17 3V66_AGP (Disabled/Enabled) Bit 6 16 3V66_1 (Disabled/Enabled) Bit 5 15 3V66_0 (Disabled/Enabled) Bit 4 -- Reserved Drive to ’0’ (Active/Inactive) Bit 3 -- Reserved Drive to ’0’ (Active/Inactive) Bit 2 -- Reserved Drive to ’0’ (Active/Inactive) Bit 1 -- Reserved Drive to ’0’ (Active/Inactive) Bit 0 -- Reserved Drive to ’0’ (Active/Inactive) Note: 9. Inactive means outputs are held LOW and are disabled from switching. These outputs are designed to be configured at power-on and are not expected to be configured during the normal modes of operation. Document #: 38-07233 Rev. *A Page 9 of 17 W254B Byte 3: Control Register (1 = Enable, 0 = Disable) Bit Pin# Bit 7 - Bit 6 Name Pin Description Reserved Drive to ’0’ (Active/Inactive) 13 PCI6 (Disabled/Enabled) Bit 5 12 PCI5 (Disabled/Enabled) Bit 4 11 PCI4 (Disabled/Enabled) Bit 3 10 PCI3 (Disabled/Enabled) Bit 2 8 PCI2 (Disabled/Enabled) Bit 1 7 PCI1/FS1 (Disabled/Enabled) Bit 0 -- SDRAM 133-MHz Mode Enable Default is Disabled = ‘0’, Enabled = ’1’ Byte 4: Control Register (1 = Enable, 0 = Disable) Bit Bit 7 Pin# 19 Name Pin Description (Disabled/Enabled) VCH_CLK SSC Mode 0 = 48 MHz non-SSC (default) 1 = 66 MHz SSC Bit 6 - Reserved Drive to ’0’ (Active/Inactive) Bit 5 - Reserved Drive to ’0’ (Active/Inactive) Bit 4 - Reserved Drive to ’0’ (Active/Inactive) Bit 3 - Reserved Drive to ’0’ (Active/Inactive) Bit 2 - Reserved Drive to ’0’ (Active/Inactive) Reserved Drive to ’0’ (Active/Inactive) Reserved Drive to ’0’ (Active/Inactive) Bit 1 Bit 0 - Byte 5: Control Register (1 = Enable, 0 = Disable) Bit Pin# Name Pin Description Bit 7 - Reserved Drive to ‘0’ (Active/Inactive) Bit 6 - Spread Spectrum and Overclocking Mode Select. See Table 9 (Active/Inactive) Bit 5 Bit 4 - Reserved Drive to ’0’ (Active/Inactive) Bit 3 - Reserved Drive to ’0’ (Active/Inactive) Bit 2 - Reserved Drive to ’0’ (Active/Inactive) Reserved Drive to ‘0’ (Active/Inactive) Reserved Drive to ‘0’ (Active/Inactive) Bit 1 Bit 0 - Byte 5 has been provided as an optional register to enable a greater degree of spread spectrum and overclocking performance for all PLL1 outputs. (CPU, SDRAM, DCLK, APIC, PCI, 3V66 and VCH_CLK) Document #: 38-07233 Rev. *A (Active/Inactive) By enabling Byte 5, (bits 5 and 6) spread spectrum can be increased to +0.5% and /or overclocking of either 5%, 10% or 15% can be enabled. It is not necessary to access Byte 5 if these additional features are not implemented. All outputs will default to 0% overclocking upon power up, with either 0% or –0.5% spread spectrum. Page 10 of 17 W254B Table 9. Spread Spectrum and Overclocking Mode Select Byte 0 Bit 3 Spread Spectrum ON Spread Spectrum OFF Byte 5 Bit 5 Bit 6 SS % Overclock % 0 0 Description and Comments 0 –0.5% 0% No overclocking (Default) 1 ±0.5% 0% No overclocking [10] 1 0 –0.5% 5% 1 1 ±0.5% 5% [10] 0 0 - 0% 0 1 - 10% [10] 1 0 - 5% [10] 1 1 - 15% [10] No overclocking Note: 10. Overclocking not tested; characterized at room temperature only. Base Frequency determined through hardware select pins, FS0 & FS1. Document #: 38-07233 Rev. *A Page 11 of 17 W254B DC Electrical Characteristics [11] Absolute Maximum DC Power Supply Parameter Description Min. Max. Unit VDD3 3.3V Core Supply Voltage –0.5 4.6 V VDDQ2 2.5V I/O Supply Voltage –0.5 3.6 V VDDQ3 3.3V Supply Voltage –0.5 4.6 V TS Storage Temperature –65 150 °C Absolute Maximum DC I/O Min. Max. Unit Vih3 Parameter 3.3V Input High Voltage Description –0.5 4.6 V Vil3 3.3V Input Low Voltage –0.5 V ESD prot. Input ESD Protection 2000 V DC Operating Requirements Parameter Description Condition Min. Max. Unit VDD3 3.3V Core Supply Voltage 3.3V±5% 3.135 3.465 V VDDQ3 3.3V I/O Supply Voltage 3.3V±5% 3.135 3.465 V VDDQ2 2.5V I/O Supply Voltage 2.5V±5% 2.375 2.625 V Vih3 3.3V Input High Voltage VDD3 2.0 VDD + 0.3 V Vil3 3.3V Input Low Voltage VSS – 0.3 0.8 V Iil Input Leakage Current[12] 0<Vin<VDD3 –5 +5 µA Voh2 2.5V Output High Voltage Ioh = (–1 mA) 2.0 Vol2 2.5V Output Low Voltage Iol = (1 mA) Voh3 3.3V Output High Voltage Ioh = (–1 mA) Vol3 3.3V Output Low Voltage Iol = (1 mA) VDD3 = 3.3V±5% VDDQ2 = 2.5V±5% V 0.4 V VDDQ3 = 3.3V±5% 2.4 V 0.4 V VDDQ3 = 3.3V±5% Vpoh3 PCI Bus Output High Voltage Ioh = (–1 mA) Vpol3 PCI Bus Output Low Voltage Iol = (1 mA) Cin Input Pin Capacitance Cxtal Xtal Pin Capacitance Cout Output Pin Capacitance Lpin Pin Inductance 2.4 V 0.55 13.5 0 V 5 pF 22.5 pF 6 pF 7 nH Ambient Temperature No Airflow 0 70 Ta Note: 11. Multiple Supplies: The voltage on any input or I/O pin cannot exceed the power pin during power-up. Power supply sequencing is NOT required. 12. Input Leakage Current does not include inputs with pull-up or pull-down resistors. Document #: 38-07233 Rev. *A °C Page 12 of 17 W254B AC Electrical Characteristics [11] TA = 0°C to +70°C, VDDQ3 = 3.3V±5%, VDDQ2= 2.5V±5% fXTL = 14.31818 MHz Spread Spectrum Function Turned Off AC clock parameters are tested and guaranteed over stated operating conditions using the stated lump capacitive load at the clock output.[13] AC Electrical Characteristics 66.6-MHz Host Parameter Description 100-MHz Host 133-MHz Host Min. Max. Min. Max. Min. Max. Unit 15.0 15.5 10.0 10.5 7.5 8.0 ns Notes TPeriod Host/CPUCLK Period 13 THIGH Host/CPUCLK High Time 5.2 N/A 3.0 N/A 1.87 N/A ns 14 TLOW Host/CPUCLK Low Time 5.0 N/A 2.8 N/A 1.67 N/A ns 15 TRISE Host/CPUCLK Rise Time 0.4 1.6 0.4 1.6 0.4 1.6 ns TFALL Host/CPUCLK Fall Time 0.4 1.6 0.4 1.6 0.4 1.6 ns TPeriod SDRAM CLK Period (100-MHz) 10.0 10.5 10.0 10.5 10.0 10.5 ns 13 THIGH SDRAM CLK High Time (100-MHz) 3.0 N/A 3.0 N/A 3.0 N/A ns 14 TLOW SDRAM CLK Low Time (100-MHz) 2.8 N/A 2.8 N/A 2.8 N/A ns 15 TRISE SDRAM CLK Rise Time (100-MHz) 0.4 1.6 0.4 1.6 0.4 1.6 ns TFALL SDRAM CLK Fall Time (100-MHz) 0.4 1.6 0.4 1.6 0.4 1.6 ns TPeriod APIC 33-MHz CLK Period 30.0 N/A 30.0 N/A 30.0 N/A ns THIGH APIC 33-MHz CLK High Time 12.0 N/A 12.0 N/A 12.0 N/A ns 14 TLOW APIC 33-MHz CLK Low Time 12.0 N/A 12.0 N/A 12.0 N/A ns 15 TRISE APIC CLK Rise Time 0.4 1.6 0.4 1.6 0.4 1.6 ns TFALL APIC CLK Fall Time 0.4 1.6 0.4 1.6 0.4 1.6 ns TPeriod 3V66 CLK Period 15.0 16.0 15.0 16.0 15.0 16.0 ns 13, 17 THIGH 3V66 CLK High Time 5.25 N/A 5.25 N/A 5.25 N/A ns 14 TLOW 3V66 CLK Low Time 5.05 N/A 5.05 N/A 5.05 N/A ns 15 TRISE 3V66 CLK Rise Time 0.5 2.0 0.5 2.0 0.5 2.0 ns TFALL 3V66 CLK Fall Time 0.5 2.0 0.5 2.0 0.5 2.0 ns TPeriod PCI CLK Period 30.0 N/A 30.0 N/A 30.0 N/A 13, 17 THIGH PCI CLK High Time 12.0 N/A 12.0 N/A 12.0 N/A 14 TLOW PCI CLK Low Time 12.0 N/A 12.0 N/A 12.0 N/A 15 TRISE PCI CLK Rise Time 0.5 2.0 0.5 2.0 0.5 2.0 TFALL PCI CLK Fall Time 0.5 2.0 0.5 2.0 0.5 2.0 tpZL, tpZH Output Enable Delay (All outputs) 30.0 N/A 30.0 N/A 30.0 N/A ns tpLZ, tpZH Output Disable Delay (All outputs) 12.0 N/A 12.0 N/A 12.0 N/A ns tstable All Clock Stabilization from Power-Up 12.0 N/A 12.0 N/A 12.0 N/A ms 13, 16 Notes: 13. Period, jitter, offset, and skew measured on rising edge at 1.25 for 2.5V clocks and at 1.5V for 3.3V clocks. 14. The time specified is measured from when VDDQ3 achieves its nominal operating level (typical condition VDDQ3 = 3.3V) until the frequency output is stable and operating within specification. 15. TRISE and TFALL are measured as a transition through the threshold region Vol = 0.4V and Voh = 2.0V (1 mA) JEDEC specification. 16. TLOW is measured at 0.4V for all outputs. 17. THIGH is measured at 2.0V for 2.5V outputs, 2.4V for 3.3V outputs. Document #: 38-07233 Rev. *A Page 13 of 17 W254B Group Skew and Jitter Limits Output Group Pin-Pin Skew Max. Cycle-Cycle Jitter Duty Cycle Nom Vdd Skew, Jitter Measure Point CPU 150 ps 250 ps 45/55 2.5V 1.25V SDRAM 250 ps 250 ps 45/55 3.3V 1.5V APIC 250 ps 500 ps 45/55 2.5V 1.25V 48MHz N/A 500 ps 45/55 3.3V 1.5V 3V66 175 ps 500 ps 45/55 3.3V 1.5V PCI 500 ps 500 ps 45/55 3.3V 1.5V REF N/A 1000 ps 45/55 3.3V 1.5V VCH_CLK N/A 250 ps 45/55 3.3V 1.5V Output Buffer Test Point Test Load Clock Output Wave TPERIOD Duty Cycle THIGH 2.0 2.5V Clocking Interface 1.25 0.4 TLOW TRISE TFALL TPERIOD Duty Cycle THIGH 2.4 3.3V Clocking Interface 1.5 0.4 TLOW TRISE TFALL Figure 10. Output Buffer Ordering Information Ordering Code W254B Document #: 38-07233 Rev. *A Package Name X Package Type 48-pin TSSOP (6.1 mm) Page 14 of 17 W254B Layout Diagram +2.5V Supply +3.3V Supply FB FB VDDQ2 VDDQ3 C4 0.005 µF G G G 10 µF G 1 2 3 4 5 6 7 8 9 10 VDDQ3 10Ω C5 G G C6 V G G G V G 11 12 G 13 G 14 V 15 GG 16 17 18 19 20 21 22 23 24 G 48 47 V 46 V 45 G 44 43 42 41 G 40 39 V 38 G 37 36 35 34 33 G 32 V 31 G G 30 29 28 27 G 26 Core V 25 10 µF 0.005 µF G G C2 µ G W254B G C1 C3 G G G G G FB = Dale ILB1206 - 300 (300Ω @ 100 MHz) Ceramic Caps C1, C3 & C5 = 10–22 µF C2 & C4 = 0.005 µF C6 = 0.1 µF G = VIA to GND plane layer V =VIA to respective supply plane layer Note: Each supply plane or strip should have a ferrite bead and capacitors Document #: 38-07233 Rev. *A Page 15 of 17 W254B Package Diagram 48-Pin Thin Shrink Small Outline Package (TSSOP, 6.1 mm) Document #: 38-07233 Rev. *A Page 16 of 17 © Cypress Semiconductor Corporation, 2001. The information contained herein is subject to change without notice. Cypress Semiconductor Corporation assumes no responsibility for the use of any circuitry other than circuitry embodied in a Cypress Semiconductor product. Nor does it convey or imply any license under patent or other rights. Cypress Semiconductor does not authorize its products for use as critical components in life-support systems where a malfunction or failure may reasonably be expected to result in significant injury to the user. The inclusion of Cypress Semiconductor products in life-support systems application implies that the manufacturer assumes all risk of such use and in doing so indemnifies Cypress Semiconductor against all charges. W254B Document Title: W254B 133-MHz Spread Spectrum FTG for Mobile Pentium® III Platforms Document Number: 38-07233 REV. ECN NO. Issue Date Orig. of Change Description of Change ** 110498 11/07/01 SZV Change from Spec number: 38-00927 to 38-07233 *A 122847 12/22/02 RBI Added power up requirements to DC and AC Electrical Characteristics. Document #: 38-07233 Rev. *A Page 17 of 17