Preliminary W83194R-37/-58 100 MHZ AGP CLOCK FOR VIA CHIPSET 1.0 GENERAL DESCRIPTION The W83194R-37/-58 is a Clock Synthesizer for VIA chipset. W83194R-37 provides all clocks required for high-speed RISC or CISC microprocessor such as Intel PentiumPro, AMD or Cyrix. Eight different frequencies of CPU, W83194R-58 provides all clocks required for high-speed RISC or CISC microprocessor such as Intel PentiumII and also provides 16 different frequencies of CPU clocks by software setting (additional register0 bit2). AGP and PCI clocks are externally selectable with smooth transitions. The W83194R-37/-58 provides AGP clocks especially for clone chipset, and makes SDRAM in synchronous frequency with CPU or AGP clocks. The W83194R-37/-58 provides I2C serial bus interface to program the registers to enable or disable each clock outputs and choose the 0.25%, 0.5% or 0.5%,1.5% center type spread spectrum to reduce EMI. The W83194R-37/-58 accepts a 14.318 MHz reference crystal as its input and runs on a 3.3V supply. High drive PCI and SDRAM CLOCK outputs typically provide greater than 1V /nS slew rate into 30 pF loads. CPU CLOCK outputs typically provide better than 1V /nS slew rate into 20 pF loads as maintaining 50 5% duty cycle. The fixed frequency outputs as REF, 24 MHz, and 48 MHz provide better than 0.5V /nS slew rate. 2.0 FEATURES 2 * Supports Pentium, Pentium Pro, Pentium II, AMD and Cyrix CPUs with I C. * 4 CPU clocks * 12 SDRAM clocks for 3 DIMs * Two AGP clocks * 6 PCI synchronous clocks. * Optional single or mixed supply: (VDD = VDDq3 = VDDq2 = VDDq2b = 3.3V) or (VDD = VDDq3 = VDDq2 = 3.3V, VDDq2b = 2.5V) * Skew form CPU to PCI clock -1 to 4 nS, center 2.6 nS, AGP to CPU sync. skew 0 nS (250 pS) * SDRAM frequency synchronous to CPU or AGP clocks * Smooth frequency switch with selections from 60 to 100 MHz CPU (-37) and 66 to 150 MHz (-58) 2 2 * I C 2-Wire serial interface and I C read back * 0.5% or 1.5% (-37) and 0.25%, 0.5% (-58) center type spread spectrum to reduce EMI * Programmable registers to enable/stop each output and select modes (mode as Tri-state or Normal) * MODE pin for power Management * 48 MHz for USB * 24 MHz for super I/O * Packaged in 48-pin SSOP -1- Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 3.0 PIN CONFIGURATION 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 VDD * REF0/CPU3.3#_2.5 Vss Xin Xout VDDq3 PCICLK_F/*FS1 PCICLK0/*FS2 Vss PCICLK1 PCICLK2 PCICLK3 PCICLK4 VDDq3 AGP0 Vss CPU_STOP#/SDRAM11 PCI_STOP#/SDRAM10 VDDq3 SDRAM 9 SDRAM 8 Vss SDATA SDCLK 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 VDDq2 AGP1 REF1/*SD_SEL# Vss CPUCLK0 CPUCLK1 VDDq2 b CPUCLK2 CPUCLK3 Vss SDRAM 0 SDRAM 1 VDDq3 SDRAM 2 SDRAM 3 Vss SDRAM 4 SDRAM 5 VDDq3 SDRAM 6 SDRAM 7 Vss 48MHz/*FS0 24MHz/*MODE 4.0 BLOCK DIAGRAM 48MHz PLL2 /2 a X1 X2 24MHz XTAL OSC REF(0:1 2 ) STOP PLL1 STOP Spread Spectrum *FS(0:2) 3 *MODE CPU3.3#_2.5 *SD_SEL# CPU_STOP# LATCH POR a 5 PCI clock Divder 2 4 12 3 STOP 5 AGP(0:1) CPUCLK(0:3) SDRAM(0:11) PCICLK(0:4) PCICLK_F CPU_STOP# PCI_STOP# *SDATA *SCLK Control Logic Config. Reg. PCI_STOP# -2- Preliminary W83194R-37/-58 5.0 PIN DESCRIPTION IN - Input OUT - Output I/O - Bi-directional Pin # - Active Low * - Internal 250k pull-up 5.1 Crystal I/O SYMBOL PIN I/O Xin 4 IN Xout 5 FUNCTION Crystal input with internal loading capacitors and feedback resistors. OUT Crystal output at 14.318 MHz nominally. 5.2 CPU, SDRAM, PCI Clock Outputs SYMBOL PIN CPUCLK [ 0:3 ] 40, 41, 43, 44 AGP[ 0:1] 15, 47 SDRAM11/ 17 I/O If MODE = 1 (default), then this pin is a SDRAM clock buffered output of the crystal. If MODE = 0, then this pin is CPU_STOP# input used in power management mode for synchronously stopping the all CPU clocks. SDRAM10/ PCI_STOP# 18 I/O If MODE = 1 (default), then this pin is a SDRAM clock output. If MODE = 0, then this pin is PCI_STOP # and used in power management mode for synchronously stopping the all PCI clocks. SDRAM [ 0:9] 20, 21, 28, 29, 31, 32, 34, 35, 37, 38 PCICLK_F/ *FS1 7 CPU_STOP# I/O FUNCTION OUT Low skew (< 250 pS) clock outputs for host frequencies such as CPU, Chipset and Cache. VDDq2b is the supply voltage for these outputs. OUT Accelerate Graphic Port clock outputs O SDRAM clock outputs which have the same frequency as CPU clocks. I/O Latched input for FS1 at initial power up for H/W selecting the output frequency of CPU, SDRAM and PCI clocks. Free running PCI clock during normal operation. PCICLK 0/ *FS2 8 I/O Latched input for FS2 at initial power up for H/W selecting the output frequency of CPU, SDRAM and PCI clocks. PCI clock during normal operation. PCICLK [ 1:4 ] 10, 11, 12, 13 OUT Low skew (< 250 pS) PCI clock outputs. -3- Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 5.3 I2C Control Interface SYMBOL PIN I/O FUNCTION 2 SDATA 23 I/O Serial data of I C 2-wire control interface SDCLK 24 IN Serial clock of I2C 2-wire control interface 5.4 Fixed Frequency Outputs SYMBOL PIN REF0/ CPU3.3#_2.5 2 I/O FUNCTION I/O Internal 250 K pull-up. Latched input for CPU3.3#_2.5 at initial power up. Reference clock during normal operation. Latched high - VDDq2b = 2.5V Latched low - VDDq2b = 3.3V REF1/*SD_SEL# 46 I/O Internal 250 K pull-up. Latched input at Power On selects either CPU(SDSEL = 1) or AGP(SD_SEL = 0) frequencies for SDRAM clock outputs. 24MHz/ *MODE 25 I/O Internal 250 K pull-up. Latched input for MODE at initial power up. 24 MHz output for super I/O during normal operation. 48MHz/ *FS0 26 I/O Internal 250 K pull-up. Latched input for FS0 at initial power up for H/W selecting the output frequency of CPU, SDRAM and PCI clocks. 48 MHz output for USB during normal operation. 5.5 Power Pins SYMBOL PIN VDD 1 Power supply for Ref [0:1] crystal and core logic. VDDq2 42 Power supply for AGP1 and REF1 output, either 2.5V or 3.3V. VDDq2b 48 Power supply for CPUCLK[0:3], either 2.5V or 3.3V. VDDq3 Vss FUNCTION 6, 14, 19, 30, 36 Power supply for SDRAM, PCICLK and 48/24 MHz outputs. 3, 9, 16, 22, 27, Circuit Ground. 33, 39, 45 -4- Preliminary W83194R-37/-58 6.0 FREQUENCY SELECTION BY HARDWARE 6.1 W83194R-37 Frequency Selection Table FS2 FS1 FS0 CPU (MHz) SDRAM (MHz) SD_SEL = 1 SD_SEL = 0 PCI (MHz) AGP (MHz) REF (MHz) 0 0 0 60 60 60 30 60 14.318 0 0 1 66.8 66.8 66.8 33.4 66.8 14.318 0 1 0 68.5 68.5 68.5 34.25 68.5 14.318 0 1 1 75 75 75 37.5 75 14.318 1 0 0 75 75 60 30 60 14.318 1 0 1 83.3 83.3 66.6 33.3 66.6 14.318 1 1 0 95 95 63.4 31.7 63.4 14.318 1 1 1 100 100 66.6 33.3 66.6 14.318 PCI (MHz) AGP (MHz) REF (MHz) 6.2 W83194R-58 Frequency Selection Table FS2 FS1 FS0 CPU (MHz) SDRAM (MHz) SD_SEL = 1 SD_SEL = 0 0 0 0 112 112 74.7 37.3 74.7 14.318 0 0 1 66.8 66.8 66.8 33.4 66.8 14.318 0 1 0 124 124 82.5 41.3 82.5 14.318 0 1 1 75 75 75 37.5 75 14.318 1 0 0 133.3 133.3 88.7 44.3 88.7 14.318 1 0 1 83.3 83.3 66.6 33.3 66.6 14.318 1 1 0 95.25 95.25 63.5 31.75 63.5 14.318 1 1 1 100.2 100.2 66.8 33.4 66.8 14.318 7.0 CPU 3.3#_2.5 BUFFER SELECTION CPU 3.3#_2.5 (Pin 2) Input Level CPU Operate at 1 VDD = 2.5V 0 VDD = 3.3V -5- Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 8.0 FUNCTION DESCRIPTION 8.1 Power Management Functions All clocks can be individually enabled or disabled via the 2-wire control interface. On power up, external circuitry should allow 3 mS for the VCO to stabilize prior to enabling clock outputs to assure correct pulse widths. When MODE = 0, pins 18 and 17 are inputs (PCI_STOP#), (CPU_STOP#), when MODE = 1, these functions are not available. A particular clock could be enabled as both the 2-wire serial control interface and one of these pins indicate that it should be enabled. The W83194R-37/-58 may be disabled in the low state according to the following table in order to reduce power consumption. All clocks are stopped in the low state, but maintain a valid high period on transitions from running to stop. The CPU and PCI clocks transform between running and stop by waiting for one positive edge on PCICLK_F followed by negative edge on the clock of interest, after which high levels of the output are either enabled or disabled. CPU_STOP# 0 0 1 1 PCI_STOP# 0 1 0 1 CPU & AGP Low Low Running Running PCI Low Running Low Running OTHER CLKs Running Running Running Running XTAL & VCOs Running Running Running Running 8.2 2-Wire I2C Control Interface The clock generator is a slave I2C component which can be read back the data stored in the latches for verification. All proceeding bytes must be sent to change one of the control bytes. The 2-wire control interface allows each clock output individually enabled or disabled. On power up, the W83194R-37/-58 initializes with default register settings, and then it optional to use the 2-wire control interface. The SDATA signal only changes when the SDCLK signal is low, and is stable when SDCLK is high during normal data transfer. There are only two exceptions. One is a high-to-low transition on SDATA while SDCLK is high used to indicate the beginning of a data transfer cycle. The other is a low-to-high transition on SDATA while SDCLK is high used to indicate the end of a data transfer cycle. Data is always sent as complete 8-bit bytes followed by an acknowledge generated. Byte writing starts with a start condition followed by 7-bit slave address [1101 0010], command code checking [0000 0000], and byte count checking. After successful reception of each byte, an acknowledge (low) on the SDATA wire will be generated by the clock chip. Controller can start to write to internal I2C registers after the string of data. The sequence order is as follows: Bytes sequence order for I2C controller: Clock Address A(6:0) & R/W Ack 8 bits dummy Command code Ack 8 bits dummy Byte count Ack Byte0,1,2... until Stop Ack Byte2, 3, 4... until Stop Set R/W to 1 when read back the data sequence is as follows: Clock Address A(6:0) & R/W Ack Byte 0 Ack -6- Byte 1 Preliminary W83194R-37/-58 8.3 Serial Control Registers The Pin column lists the affected pin number and the @PowerUp column gives the state at true power up. Registers are set to the values shown only on true power up. "Command Code" byte and "Byte Count" byte must be sent following the acknowledge of the Address Byte. Although the data (bits) in these two bytes are considered "don't care", they must be sent and will be acknowledge. After that, the below described sequence (Register 0, Register 1, Register 2, ....) will be valid and acknowledged. 8.3.1 Register 0: CPU Frequency Select Register BIT 7 @POWERUP 0 PIN - 6 5 4 3 0 0 0 0 - 2 0 - 2 0 - 1 0 - 0 0 - DESCRIPTION 0 = 1.5% Spread Spectrum Modulation (W83194R-37) 1 = 0.5% Spread Spectrum Modulation 0 = 0.25% Center Type Spread Spectrum Modulation (W83194R58) 1 = 0.5% Center Type Spread Spectrum Modulation SSEL2 (Frequency table selection by software via I2C) SSEL1 (Frequency table selection by software via I2C) SSEL0 (Frequency table selection by software via I2C) 0 = Selection by hardware 1 = Selection by software I2C - Bit 6:4 SSEL3 (Frequency table selection by software via I2C for W83194R-58) 0 = Spread spectrum center type (W83194R-37) 1 = Spread spectrum down type (W83194R-37) 0 = Normal 1 = Spread Spectrum enabled 0 = Running 1 = Tristate all outputs W83194R-37 Frequency table selection by software via I2C SSEL2 0 SSEL1 0 SSEL0 0 CPU(MHz) 60 SDRAM (MHz) PCI AGP SD_SEL=1 SD_SEL=0 (MHz) (MHz) 60 60 30 60 REF (MHz) 14.318 0 0 1 66.8 66.8 66.8 33.4 66.8 14.318 0 1 0 68.5 68.5 68.5 34.25 68.5 14.318 0 1 1 75 75 75 37.5 75 14.318 1 0 0 75 75 60 30 60 14.318 1 0 1 83.3 83.3 66.6 33.3 66.6 14.318 1 1 0 95 95 63.4 31.7 63.4 14.318 1 1 1 100 100 66.6 33.3 66.6 14.318 -7- Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 W83194R-58 Frequency table selection by software via I2C SSEL2 SSEL1 SSEL0 Register0 Bit2 CPU SDRAM (MHz) PCI AGP REF SSEL3 (MHz) SD_SEL=1 SD_SEL=0 (MHz) (MHz) (MHz) 0 0 0 0 112 112 74.7 37.3 74.7 14.318 0 0 1 0 66.8 66.8 66.8 33.4 66.8 14.318 0 1 0 0 124 124 82.7 41.3 82.7 14.318 0 1 1 0 75 75 75 37.5 75 14.318 1 0 0 0 133.3 133.3 88.7 44..3 88.7 14.318 1 0 1 0 83.3 83.3 66.6 33.3 66.6 14.318 1 1 0 0 95.25 95.25 63.5 31.75 63.5 14.318 1 1 1 0 100.2 100.2 66.8 33.4 66.8 14.318 0 0 0 1 103 103 68.7 34.3 68.7 14.318 0 0 1 1 112 112 74.7 37.3 74.7 14.318 0 1 0 1 115 115 76.6 38.3 76.6 14.318 0 1 1 1 120 120 80 40 80 14.318 1 0 0 1 124 124 82 31 82 14.318 1 0 1 1 133.3 133.3 66.6 33.3 66.6 14.318 1 1 0 1 140 140 70 35 70 14.318 1 1 1 1 150 150 75 37.5 75 14.318 FUNCTION TABLE FUNCTION OUTPUTS DESCRIPTION CPU PCI SDRAM REF IOAPIC TRI-STATE Hi-Z Hi-Z Hi-Z Hi-Z Hi-Z NORMAL See table See table CPU 14.318 14.318 8.3.2 Register 1: CPU, 48/24 MHz Clock Register (1 = Active, 0 = Inactive) BIT @POWERUP PIN DESCRIPTION 7 1 - Reserved 6 1 - Reserved 5 1 - Reserved 4 1 - Reserved -8- Preliminary W83194R-37/-58 8.3.2 Register 1: CPU, 48/24 MHz Clock Register (1 = Active, 0 = Inactive), continued BIT @POWERUP PIN DESCRIPTION 3 1 40 CPUCLK3 (Active/Inactive) 2 1 41 CPUCLK2 (Active/Inactive) 1 1 43 CPUCLK1 (Active/Inactive) 0 1 44 CPUCLK0 (Active/Inactive) 8.3.3 Register 2: PCI Clock Register (1 = Active, 0 = Inactive) BIT @POWERUP PIN DESCRIPTION 7 x - Reserved 6 1 7 PCICLK_F (Active/Inactive) 5 1 15 AGP0 (Active/Inactive) 4 1 14 PCICLK4 (Active/Inactive) 3 1 12 PCICLK3 (Active/Inactive) 2 1 11 PCICLK2 (Active/Inactive) 1 1 10 PCICLk1 (Active/Inactive) 0 1 8 PCICLK0 (Active/Inactive) 8.3.4 Register 3: SDRAM Clock Register (1 = Active, 0 = Inactive) BIT @POWERUP PIN 7 1 28 SDRAM7 (Active/Inactive) DESCRIPTION 6 1 29 SDRAM6 (Active/Inactive) 5 1 31 SDRAM5 (Active/Inactive) 4 1 32 SDRAM4 (Active/Inactive) 3 1 34 SDRAM3 (Active/Inactive) 2 1 35 SDRAM2 (Active/Inactive) 1 1 37 SDRAM1 (Active/Inactive) 0 1 38 SDRAM0 (Active/Inactive) 8.3.5 Register 4: Additional SDRAM Clock Register (1 = Active, 0 = Inactive) BIT @POWERUP PIN DESCRIPTION 7 x - Reserved 6 x - Reserved -9- Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 8.3.5 Register 4: Additional SDRAM Clock Register (1 = Active, 0 = Inactive), continued BIT @POWERUP PIN DESCRIPTION 5 x - Reserved 4 x - Reserved 3 1 17 SDRAM11 (Active/ Inactive) 2 1 18 SDRAM10 (Active/ Inactive) 1 1 20 SDRAM9 (Active/ Inactive) 0 1 21 SDRAM8 (Active/ Inactive) 8.3.6 Register 5: Peripheral Control (1 = Active, 0 = Inactive) BIT @POWERUP PIN DESCRIPTION 7 x - Reserved 6 x - Reserved 5 x - Reserved 4 1 47 3 x - Reserved 2 x - Reserved 1 1 46 REF1 (Active/ Inactive) 0 1 2 REF0 (Active/ Inactive) AGP1 (Active/ Inactive) 8.3.7 Register 6: Reserved Register BIT @POWERUP PIN DESCRIPTION 7 x - Reserved 6 x - Reserved 5 x - Reserved 4 x - Reserved 3 x - Reserved 2 x - Reserved 1 x - Reserved 0 x - Reserved - 10 - Preliminary W83194R-37/-58 9.0 SPECIFICATIONS 9.1 Absolute Maximum Ratings Stresses greater than those listed in this table may cause permanent damage to the device. Precautions should be taken to avoid application of any voltage higher than the maximum rated voltages to this circuit. Maximum conditions for extended periods may affect reliability. Unused inputs must always be tied to an appropriate logic voltage level (Ground or VDD). PARAMETER SYMBOL RATING VDD, VIN - 0.5V to +7.0V Storage Temperature TSTG - 65C to +150C Ambient Temperature TB - 55C to +125C Operating Temperature TA 0C to +70C Voltage on any pin with respect to GND Note: Exposure to conditions beyond those listed under Absolute Maximum Ratings may adversely affect the life and reliability of the device. 9.2 AC Characteristics VDDq2 = VDD = VDDq3 = 3.3V 5%, VDDq2b = 2.375V~2.9V , TA = 0 C to +70 C PARAMETER SYM. MIN. TYP. MAX. UNITS 45 50 55 % Measured at 1.5V 4 nS 15 pF Load Measured at 1.5V tSKEW 250 pS 15 pF Load Measured at 1.5V tCCJ 250 pS tJA 500 pS BWJ 500 KHz 0.4 1.6 nS 15 pF Load on CPU and PCI outputs Output Duty Cycle CPU/SDRAM to PCI Offset Skew (CPU-CPU), (PCIPCI), (SDRAM-SDRAM) CPU/SDRAM tOFF 1 TEST CONDITIONS Cycle to Cycle Jitter CPU/SDRAM Absolute Jitter Jitter Spectrum 20 dB Bandwidth from Center Output Rise (0.4V-2.0V) tTLH & Fall (2.0V-0.4V) Time tTHL Overshoot/Undershoot Vover 0.7 1.5 V 22 at source of 8 inch PCB run to 15 pF load VRBE 0.7 2.1 V Ring Back must not enter this range. Beyond Power Rails Ring Back Exclusion - 11 - Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 9.3 DC Characteristics VDDq2 = VDD = VDDq3 = 3.3V 5%, VDDq2b = 2.375V~2.9V, TA = 0 C to +70 C PARAMETER SYM. MIN. TYP. MAX. UNITS 0.8 Vdc TEST CONDITIONS Input Low Voltage VIL Input High Voltage VIH Input Low Current IIL -66 A Input High Current IIH 5 A VOL 0.4 Vdc All outputs Vdc All outputs using 3.3V power Output Low Voltage 2.0 Vdc IOL = 4 mA Output High Voltage IOH = 4 mA VOH 2.4 Tri-State leakage Current IOZ Dynamic Supply Current for VDD + VDDq3 IDD3 Dynamic Supply Current for VDDq2 + VDDq2b IDD2 mA Same as above CPU Stop Current for VDD + VDDq3 ICPUS3 mA Same as above CPU Stop Current for VDDq2 + VDDq2b ICPUS2 mA Same as above IPD3 mA A 10 mA CPU = 66.6 MHz PCI = 33.3 MHz with load PCI Stop Current for VDD + VDDq3 9.4 Buffer Characteristics 9.4.1 Type 1 Buffer for CPU (0:3) PARAMETER SYMBOL MIN. Pull-up Current Min. IOH (min.) -27 Pull-up Current Max. IOH (max.) Pull-down Current Min. IOL (min.) Pull-down Current Max. IOL (max.) Rise/Fall Time Min. Between 0.4V and 2.0V TRF (min.) Rise/Fall Time Max. Between 0.4V and 2.0V TRF (max.) TYP. MAX. -27 27 0.4 1.6 - 12 - UNITS TEST CONDITIONS mA Vout = 1.0V mA Vout = 2.0V mA Vout = 1.2V mA Vout = 0.3V nS 10 pF Load nS 20 pF Load Preliminary W83194R-37/-58 9.4.2 Type 2 Buffer for IOAPIC PARAMETER SYMBOL Pull-up Current Min. IOH (min.) Pull-up Current Max. IOH (max.) Pull-down Current Min. IOL (min.) Pull-down Current Max. IOL (max.) Rise/Fall Time Min. Between 0.7V and 1.7V TRF (min.) Rise/Fall Time Max. Between 0.7V and 1.7V TRF (max.) MIN. TYP. MAX. UNITS TEST CONDITIONS mA Vout = 1.4V mA Vout = 2.7V mA Vout = 1.0V mA Vout = 0.2V nS 10 pF Load 1.8 nS 20 pF Load MAX. UNITS -29 28 0.4 9.4.3 Type 3 Buffer for REF(0:1), 24 MHz, 48 MHz PARAMETER SYMBOL MIN. Pull-up Current Min. IOH (min.) -29 Pull-up Current Max. IOH (max.) Pull-down Current Min. IOL (min.) Pull-down Current Max. IOL (max.) Rise/Fall Time Min. Between 0.8V and 2.0V TRF (min.) Rise/Fall Time Max. TRF (max.) TYP. TEST CONDITIONS mA Vout = 1.0V mA Vout = 3.135V mA Vout = 1.95V mA Vout = 0.4V nS 10 pF Load 4.0 nS 20 pF Load MAX. UNITS -23 29 1.0 Between 0.8V and 2.0V 9.4.4 Type 4 Buffer for REF0 and SDRAM (0:11) PARAMETER SYMBOL Pull-up Current Min. IOH (min.) Pull-up Current Max. IOH (max.) Pull-down Current Min. IOL (min.) Pull-down Current Max. IOL (max.) Rise/Fall Time Min. Between 0.8V and 2.0V TRF (min.) Rise/Fall Time Max. TRF (max.) MIN. TYP. -46 53 0.5 1.3 TEST CONDITIONS mA Vout = 1.65V mA Vout = 3.135V mA Vout = 1.65V mA Vout = 0.4V nS 20 pF Load nS 30 pF Load Between 0.8V and 2.0V - 13 - Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 9.4.5 Type 5 Buffer for PCICLK(0:4,F) PARAMETER SYM. MIN. Pull-up Current Min. IOH (min.) -33 Pull-up Current Max. IOH (max.) Pull-down Current Min. IOL (min.) Pull-down Current Max. IOL (max.) Rise/Fall Time Min. Between 0.8V and 2.0V TRF (min.) Rise/Fall Time Max. TRF (max.) TYP. MAX. UNITS -33 30 38 0.5 2.0 TEST CONDITIONS mA Vout = 1.0V mA Vout = 3.135V mA Vout = 1.95V mA Vout = 0.4V nS 15 pF Load nS 30 pF Load Between 0.8V and 2.0V 10.0 POWER MANAGEMENT TIMING 10.1 CPU_STOP# Timing Diagram CPUCLK (Internal) 1 2 1 2 PCICLK (Internal) PCICLK_F CPU_STOP# CPUCLK[0:3] SDRAM For synchronous Chipset, CPU_STOP# pin is a synchronous "active low" input pin used to stop the CPU clocks for low power operation. This pin is asserted synchronously by the external control logic at the rising edge of free running PCI clock(PCICLK_F). All other clocks will continue to run while the CPU clocks are stopped. The CPU clocks will always be stopped in a low state and resume output with full pulse width. In this case, CPU "clocks on latency" is less than 2 CPU clocks and clocks off latency is less then 2 CPU clocks. - 14 - Preliminary W83194R-37/-58 10.2 PCI_STOP# Timing Diagram CPUCLK (Internal) 1 PCICLK (Internal) 1 2 2 PCICLK_F PCI_STOP# PCICLK[0:4] For synchronous Chipset, PCI_STOP# pin is a synchronous "active low" input pin used to stop the PCICLK [0:4] for low power operation. This pin is asserted synchronously by the external control logic at the rising edge of free running PCI clock (PCICLK_F). All other clocks will continue to run while the PCI clocks are stopped. The PCI clocks will always be stopped in a low state and resume output with full pulse width. In this case, PCI "clocks on latency" is less than 1 PCI clocks and clocks off latency is less then 1 PCI clocks. 11.0 OPERATION OF DUAL FUCTION PINS Pins 2, 7, 8, 25 and 26 are dual function pins and are used for selecting different functions in this device (see Pin description). During power up, these pins are in input mode (see Figure 1), therefore, and are considered input select pins. When VDD reaches 2.5V, the logic level that is present on these pins are latched into their appropriate internal registers. Once the correct information are properly latched, these pins will change into output pins and will be pulled low by default. At the end of the power up timer (within 3 mS) outputs starts to toggle at the specified frequency. 2.5V #2 REF0/CPU3.3#_2.5 #7 PCICLK_F/FS1 #8 PCICLK0/FS2 #25 24/MODE #26 48/FS0 Output tri-state VDD Output pull-low Within 3 mS Input All other clocks Output tri-state Output Output pull-low - 15 - Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 Each of these pins are a large pull-up resistor (250 K @3.3V) inside. The default state will be logic 1, but the internal pull-up resistor may be too large when long traces or heavy load appear on these dual function pins. Under these conditions, an external 10 K resistor is recommended to be connected to VDD if logic 1 is expected. Otherwise, the 10 K resistor is connected to ground if a logic 0 is desired. The 10 K resistor should be place before the serious terminating resistor. Note that these logic will only be latched at initial power on. If optional EMI reducing capacitor are needed, they should be placed as close to the series terminating resistor as possible and after the series terminating resistor. These capacitor has typical values ranging from 4.7 pF to 22 pF. VDD Series 10 K Terminating Resistor Device Pin Clock Trace EMI Reducing Cap 10 K Optional Ground Ground Programming Header VDD Pad Ground Pad 10 K Series Terminating Resistor Device Pin Clock Trace EMI Reducing Cap Optional Ground - 16 - Preliminary W83194R-37/-58 12.0 POWER SUPPLY SUGGESTION 1. A solid ground plane should be placed around the clock device. Ground connections should be tied to this main ground plane as short as possible. No cuts should be made in the ground plane around the device. 2. C21, C22, C31, C36 are decoupling capacitors (0.1 F surface mount, low ESR, ceramic capacitors.) They should be placed as possible as the VDD pin and the ground via. 3. C1 and C2 are supply filtering capacitors for low frequency power supply noise. A 22 F (or 10 F) tantalum capacitor is recommended. 4. Use of Ferrite Bead (FB) are recommended to further reduce the power supply noise. 5. The power supply race to the VDD pins must be thick enough so that voltage drops across the trace resistance is negligible. VDD (3.3V) C1 FB2 FB1 VDD Plane C31 C32 C33 C34 VDD2 Plane 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 31 30 29 28 27 26 25 - 17 - C21 VDD2 (3.3Vor2.5V) C2 C22 C36 C35 Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 13.0 ORDERING INFORMATION PART NUMBER PACKAGE TYPE PRODUCTION FLOW W83194R-37/-58 48-pin SSOP Commercial, 0 C to +70 C 14.0 HOW TO READ THE TOP MARKING W83194R-37 28051234 814GBB W83194R-58 28051234 814GBB 1st line: Winbond logo and the type number: W83194R-37/-58 2nd line: Tracking code 2 8051234 2: wafers manufactured in Winbond FAB 2 8051234: wafer production series lot number 3rd line: Tracking code 814 G B B 814: packages made in '98, week 14 G: assembly house ID; A means ASE, S means SPIL, G means GR BB: IC revision All the trade marks of products and companies mentioned in this data sheet belong to their respective owners. - 18 - Preliminary W83194R-37/-58 15.0 PACKAGE DRAWING AND DIMENSIONS - 19 - Publication Release Date: April 13, 2005 Revision A2 Preliminary W83194R-37/-58 16.0 REVISION HISTORY VERSION DATE PAGE A2 4/13/2005 20 DESCRIPTION Add disclaimer Important Notice Winbond products are not designed, intended, authorized or warranted for use as components in systems or equipment intended for surgical implantation, atomic energy control instruments, airplane or spaceship instruments, transportation instruments, traffic signal instruments, combustion control instruments, or for other applications intended to support or sustain life. Further more, Winbond products are not intended for applications wherein failure of Winbond products could result or lead to a situation wherein personal injury, death or severe property or environmental damage could occur. Winbond customers using or selling these products for use in such applications do so at their own risk and agree to fully indemnify Winbond for any damages resulting from such improper use or sales. Headquarters Winbond Electronics (H.K.) Ltd. Rm. 803, World Trade Square, Tower II, No. 4, Creation Rd. III, 123 Hoi Bun Rd., Kwun Tong, Science-Based Industrial Park, Kowloon, Hong Kong Hsinchu, Taiwan TEL: 852-27513100 TEL: 886-3-5770066 FAX: 852-27552064 FAX: 886-3-5792646 http://www.winbond.com.tw/ Voice & Fax-on-demand: 886-2-27197006 Taipei Office 11F, No. 115, Sec. 3, Min-Sheng East Rd., Taipei, Taiwan TEL: 886-2-27190505 FAX: 886-2-27197502 Note: All data and specifications are subject to change without notice. - 20 - Winbond Electronics North America Corp. Winbond Memory Lab. Winbond Microelectronics Corp. Winbond Systems Lab. 2727 N. First Street, San Jose, CA 95134, U.S.A. TEL: 408-9436666 FAX: 408-5441798