CYPRESS W48S101

PRELIMINARY
W48S101-04
Spread Spectrum Motherboard Frequency Generator
Features
Key Specifications
• Maximized EMI suppression using Cypress’s Spread
Spectrum technology
• I2C™ interface
• Four copies of CPU output
• Eight copies of PCI clock (synchronous w/CPU output)
• Two copies of 14.318-MHz IOAPIC output
• One copy of 48-MHz USB output
• Selectable 24-/48-MHz clock-through-resistor
strapping
• Three buffered copies of 14.318-MHz reference input
• Input is a 14.318-MHz XTAL or reference signal
• Selectable 100-MHz or 66-MHz CPU outputs
• Power management control input pins
• Test mode and output three-state through I2C interface
Supply Voltages:....................................... VDDQ3 = 3.3V±5%
VDDQ2 = 2.5V±5%
CPU Cycle to Cycle Jitter: ........................................... 200 ps
CPU0:3 Output Skew: ................................................ 175 ps
PCI_F, PCI1:7 Output Skew: .......................................500 ps
CPU to PCI Output Skew: ............ 1.5 to 4.0 ns (CPU Leads)
Logic inputs and REF0/SEL48# have 250K pull-up resistors
except SEL100/66#.
Table 1. Pin Selectable Frequency
SEL
100/66#
CPU (MHz)
PCI
(MHz)
SPREAD#=0
0
66.8
33.4
±0.5% Center
1
100
33.3
±0.5% Center
Block Diagram
Pin Configuration
VDDREF
REF0/SEL48#
X1
X2
REF1
XTAL
OSC
PLL Ref Freq
VDDCORE0/1
GNDCORE0/1
APIC1
GNDAPIC
VDDCPU0
CPU_STOP#
CPU0
CPU1
GNDCPU0
VDDCPU1
CPU2
Stop
Clock
Control
100/66#_SEL
REF2
GNDREF
VDDAPIC
APIC0
PLL 1
CPU3
GNDCPU1
VDDPCI0
÷2/÷3
SPREAD#
REF0/SEL48#
REF1
GNDREF
X1
X2
GNDPCI0
PCICLK_F
PCI1
VDDPCI0
PCI2
PCI3
GNDPCI1
PCI4
PCI5
VDDPCI1
PCI6
PCI7
GNDPCI2
VDDCORE0
GNDCORE0
VDD48MHz
48MHz
24/48MHz
GND48MHz
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
[1]
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
VDDREF
REF2
VDDAPIC
APIC0
APIC1
GNDAPIC
NC
VDDCPU0
CPU0
CPU1
GNDCPU0
VDDCPU1
CPUCLK2
CPUCLK3
GNDCPU1
VDDCORE1
GNDCORE1
PCI_STOP#
CPU_STOP#
PWR_DWN#
SPREAD#
SDATA
SCLK
SEL100/66#
PCI_F
PCI2
PCI3
GNDPCI0
VDDPCI1
PCI4
PCI_STOP#
SDATA
SCLK
Note:
1. Internal pull-up resistors should not be relied upon for
setting I/O pins HIGH.
PCI1
Stop
Clock
Control
PCI5
I 2C
Logic
PCI6
PCI7
Power
Down
Control
PWR_DWN#
GNDPCI1
VDD48MHz
48MHz
PLL2
24/48MHz
GND48MHz
I2C is a trademark of Philips Corporation.
Cypress Semiconductor Corporation
•
3901 North First Street
•
San Jose
•
CA 95134 •
408-943-2600
October 27, 1999, rev. **
PRELIMINARY
W48S101-04
Pin Definitions
Pin Name
Pin No.
Pin Type
Pin Description
CPU0:3
40, 39, 36,
35
O
CPU Clock Outputs 0 through 3: These four CPU clock outputs are controlled by
the CPU_STOP# control pin. Output voltage swing is controlled by voltage applied
to VDDQ2.
PCI1:7
8, 10, 11,
13, 14, 16,
17
O
PCI Bus Clock Outputs 1 through 7: These seven PCI clock outputs are controlled
by the PCI_STOP# control pin. Output voltage swing is controlled by voltage applied
to VDDQ3.
PCI_F
7
O
Fixed PCI Clock Output: Unlike PCI1:7 outputs, this output is not controlled by the
PCI_STOP# control pin. Output voltage swing is controlled by voltage applied to
VDDQ3.
CPU_STOP#
30
I
CPU_STOP# Input: When brought LOW, clock outputs CPU0:3 are stopped LOW
after completing a full clock cycle (2–3 CPU clock latency). When brought HIGH,
clock outputs CPU0:3 start beginning with a full clock cycle (2–3 CPU clock latency).
PCI_STOP#
31
I
PCI_STOP# Input: The PCI_STOP# input enables the PCI 1:7 outputs when HIGH
and causes them to remain at logic 0 when LOW. The PCI_STOP signal is latched
on the rising edge of PCI_F. Its effect takes place on the next PCI_F clock cycle.
SPREAD#
28
I
SPREAD# Input: When brought LOW this pin activates Spread Spectrum clocking.
APIC0:1
45, 44
O
I/O APIC Clock Outputs: Provides 14.318-MHz fixed frequency. The output voltage
swing is controlled by VDDQ2.
48MHz
22
O
48-MHz Output: Fixed clock outputs at 48 MHz. Output voltage swing is controlled
by voltage applied to VDDQ3.
24/48MHz
23
O
24-MHz or 48-MHz Output: 24-MHz output when pin 1 is strapped through 10-kΩ
resistor to VDDQ3. 48-MHz output when pin 1 is strapped through 10-kΩ resistor to
GND.
REF0/SEL48#
1
I/O
I/O Dual Function REF0 and SEL48# pin: During power on, SEL48# input will be
latched, which will set pin 23 to output 24 MHz or 48 MHz. It then reverts to REF0
fixed output.
2, 47
O
Fixed 14.318-MHz Outputs 1 through 2: Used for various system applications.
Output voltage swing is controlled by voltage applied to VDDQ3.
SEL100/66#
25
I
Frequency Selection Input: Selects power-up default CPU clock frequency as
shown in Table 1 on page 1.
SCLK
26
I
Clock pin for I2C circuitry.
SDATA
27
I/O
Data pin for I2C circuitry.
X1
4
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
5
I
Crystal Connection: An input connection for an external 14.318-MHz crystal. If
using an external reference, this pin must be left unconnected.
PWR_DWN#
29
I
Power Down Control: When this input is LOW, device goes into a low-power standby condition. All outputs are actively held LOW while in power-down. CPU and PCI
clock outputs are stopped LOW after completing a full clock cycle (2–3 CPU clock
cycle latency). When brought HIGH, CPU, SDRAM and PCI outputs start with a full
clock cycle at full operating frequency (3 ms maximum latency).
VDDQ3
9, 15, 19,
21, 33, 48
P
Power Connection: Connect to 3.3V supply.
VDDQ2
46, 41, 37
P
Power Connection: Power supply for APIC0:1 and CPU0:3 output buffers. Connect
to 2.5V.
3, 6, 12, 18,
20, 24, 32,
34, 38, 43
G
Ground Connections: Connect all ground pins to the common system ground
plane.
REF1:2
GND
2
PRELIMINARY
W48S101-04
strapping resistor on the l/O pin to pull the pin and its associated capacitive clock load to either a logic HIGH or LOW state.
At the end of the 2-ms period, the established logic “0” or “1”
condition of the l/O pin is then latched. Next the output buffer
is enabled, which converts the l/O pin into an operating clock
output. The 2-ms timer is started when V DD reaches 2.0V. The
input bit can only be reset by turning VDD off and then back on
again.
Overview
The W48S101-04, a motherboard clock synthesizer, can provide either a 2.5V or 3.3V CPU clock swing, making it suitable
for a variety of CPU options. A fixed 48-MHz clock is provided
for other system functions. The W48S101-04 supports spread
spectrum clocking for reduced EMI.
Functional Description
It should be noted that the strapping resistor has no significant
effect on clock output signal integrity. The drive impedance of
clock output is 40Ω (nominal) which is minimally affected by
the 10-kΩ strap to ground or VDD. 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
VDD should be kept less than two inches in length to prevent
system noise coupling during input logic sampling.
I/O Pin Operation
Pin 1 is a dual-purpose l/O pin. Upon power-up this pin acts as
a logic input, allowing the determination of assigned device
functions. A short time after power-up, the logic state of the pin
is latched and the pin becomes a clock output. This feature
reduces device pin count by combining clock outputs with input
select pins.
An external 10-kΩ “strapping” resistor is connected between
the l/O pin and ground or VDD. Connection to ground sets a
latch to “0,” connection to VDD sets a latch to “1.” Figure 1 and
Figure 2 show two suggested methods for strapping resistor
connections.
When the clock output is enabled following the 2-ms input period, a 14.318-MHz output frequency is delivered on the pin,
assuming that VDD has stabilized. If VDD has not yet reached
full value, output frequency initially may be below target but will
increase to target once VDD voltage has stabilized. In either
case, a short output clock cycle may be produced from the
CPU clock outputs when the outputs are enabled.
Upon W48S101-04 power-up, the first 2 ms of operation is
used for input logic selection. During this period, the Reference clock output buffer is three-stated, allowing the output
VDD
Output Strapping Resistor
Series Termination Resistor
10 kΩ
(Load Option 1)
Clock Load
W48S101-04
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
Jumper Options
Output Strapping Resistor
VDD
Series Termination Resistor
10 kΩ
W48S101-04
Power-on
Reset
Timer
R
Output
Buffer
Q
Resistor Value R
Hold
Output
Low
Output Three-state
D
Data
Latch
Figure 2. Input Logic Selection Through Jumper Option
3
Clock Load
PRELIMINARY
W48S101-04
Contrast the typical clock EMI with the Cypress Spread Spectrum Clock Generation. Notice the spike in the typical clock.
This spike can make systems fail quasi-peak EMI testing. The
FCC and other regulatory agencies test for peak emissions.
With the Cypress clock, the peak energy is much lower (at
least 8 dB) because the energy is spread out across a wider
bandwidth.
Spread Spectrum Clock Generation
The benefits of using Spread Spectrum Clock Generation are
depicted in Figure 3. An EMI emission profile of a clock harmonic is shown.
5dB/div
Typ ical C lo ck
Amplitude (dB)
SS FT G
-SS %
Freq uen cy Sp an (M Hz)
+S S%
Figure 3. Typical Clock and SSCG Comparison
MIN (–0.5%)
Figure 4. Typical Modulation Profile
4
100%
90%
80%
70%
60%
50%
40%
30%
20%
10%
100%
90%
80%
70%
60%
50%
40%
30%
20%
10%
FREQUENCY
MAX (+0.5%)
PRELIMINARY
W48S101-04
outputs of the chipset. Clock device register changes are normally made upon system initialization, if required. The interface can also be used during system operation for power management functions. Table 2 summarizes the control functions
of the serial data interface.
Serial Data Interface
The W48S101-04 features a two-pin, serial data interface that
can be used to configure internal register settings that control
particular device functions. Upon power-up, the W48S101-04
initializes with default register settings. Therefore, the use of
this serial data interface is optional. The serial interface is
write-only (to the clock chip) and is the dedicated function of
device pins SDATA and SCLOCK. In motherboard applications, SDATA and SCLOCK are typically driven by two logic
Operation
Data is written to the W48S101-04 in ten bytes of eight bits
each. Bytes are written in the order shown in Table 3.
Table 2. Serial Data Interface Control Functions Summary
Control Function
Description
Common Application
Clock Output Disable
Any individual clock output(s) can be disabled. Dis- Unused outputs are disabled to reduce EMI
abled outputs are actively held LOW.
and system power. Examples are clock outputs to unused PCI slots.
CPU Clock Frequency
Selection
Provides CPU/PCI frequency selections beyond the
100- and 66.6-MHz selections that are provided by
the SEL100/66# pin. Frequency is changed in a
smooth and controlled fashion.
For alternate microprocessors and power
management options. Smooth frequency transition allows CPU frequency change under
normal system operation.
Output Three-state
Puts all clock outputs into a high-impedance state.
Production PCB testing.
Test Mode
All clock outputs toggle in relation to X1 input, inter- Production PCB testing.
nal PLL is bypassed. Refer to Table 4.
(Reserved)
Reserved function for future device revision or pro- No user application. Register bit must be writduction device testing.
ten as 0.
Table 3. Byte Writing Sequence
Byte
Sequence
Byte Name
1
Slave Address
11010010
Commands the W48S101-04 to accept the bits in Data Bytes 3–6 for
internal register configuration. Since other devices may exist on the same
common serial data bus, it is necessary to have a specific slave address
for each potential receiver. The slave receiver address for the
W48S101-04 is 11010010. Register setting will not be made if the Slave
Address is not correct (or is for an alternate slave receiver).
2
Command
Code
Don’t Care
Unused by the W48S101-04, therefore bit values are ignored (“don’t
care”). This byte must be included in the data write sequence to maintain
proper byte allocation. The Command Code Byte is part of the standard
serial communication protocol and may be used when writing to another
addressed slave receiver on the serial data bus.
3
Byte Count
Don’t Care
Unused by the W48S101-04, therefore bit values are ignored (“don’t
care”). This byte must be included in the data write sequence to maintain
proper byte allocation. The Byte Count Byte is part of the standard serial
communication protocol and may be used when writing to another addressed slave receiver on the serial data bus.
4
Data Byte 0
Don’t Care
Refer to Cypress SDRAM drivers.
5
Data Byte 1
6
Data Byte 2
7
Data Byte 3
Refer to Table 4
8
Data Byte 4
9
Data Byte 5
The data bits in these bytes set internal W48S101-04 registers that control device operation. The data bits are only accepted when the Address
Byte bit sequence is 11010010, as noted above. For description of bit
control functions, refer to Table 4, Data Byte Serial Configuration Map.
10
Data Byte 6
Bit Sequence
Byte Description
5
PRELIMINARY
Writing Data Bytes
W48S101-04
Table 5 details additional frequency selections that are available through the serial data interface.
Each bit in the data bytes controls a particular device function
except for the “reserved” bits, which must be written as a logic
0. Bits are written MSB (most significant bit) first, which is bit
7. Table 4 gives the bit formats for registers located in Data
Bytes 3–6.
Table 6 details the select functions for Byte 3, bits 1 and 0.
Table 4. Data Bytes 3–6 Serial Configuration Map
Affected Pin
Bit(s)
Pin No.
Data Byte 3
7
--
Pin Name
Bit Control
Control Function
0
1
--
--
Default
--
(Reserved)
6
--
--
SEL_2
Refer to Table 5
0
5
--
--
SEL_1
Refer to Table 5
0
Refer to Table 5
0
4
--
--
SEL_0
3
--
--
BYT0_FS#
Frequency Controlled
by external SEL100/
66# pin
Frequency Controlled
by BYT0 SEL (2:0)
0
2
--
--
(Reserved)
--
--
0
1–0
--
--
Bit 1
0
0
1
Bit 0
0
1
0
1
1
0
Function (See Table 6 for function details)
Normal Operation
Test Mode
Spread Spectrum on (See Table 5 for frequency and
spread selections. ±0.5% modulation)
All Outputs Three-stated
00
Data Byte 4
7
--
--
6
5
23
--
24/48MHz
--
(Reserved)
Clock Output Disable
(Reserved)
--
0
Active
--
1
0
4
--
--
--
--
0
3
35
CPU3
Clock Output Disable
Low
Active
1
2
36
CPU2
Clock Output Disable
Low
Active
1
1
39
CPU1
Clock Output Disable
Low
Active
1
0
40
CPU0
Clock Output Disable
Low
Active
1
Data Byte 5
7
(Reserved)
-Low
--
7
PCICLK_F
Clock Output Disable
Low
Active
1
6
17
PCI7
Clock Output Disable
Low
Active
1
5
16
PCI6
Clock Output Disable
Low
Active
1
4
14
PCI5
Clock Output Disable
Low
Active
1
3
13
PCI4
Clock Output Disable
Low
Active
1
2
1
11
10
PCI3
PCI2
Clock Output Disable
Clock Output Disable
Low
Low
Active
Active
1
1
0
8
PCI1
Clock Output Disable
Low
Active
1
--
--
(Reserved)
--
--
0
(Reserved)
Data Byte 6
7
6
--
--
5
4
44
45
IOAPIC1
IOAPIC0
Clock Output Disable
Clock Output Disable
(Reserved)
--
--
0
Low
Low
Active
Active
1
1
3
--
--
--
--
0
2
47
REF2
Clock Output Disable
Low
Active
1
1
2
REF1
Clock Output Disable
Low
Active
1
0
1
REF0
Clock Output Disable
Low
Active
1
6
PRELIMINARY
W48S101-04
Table 5. Additional Frequency Selections through Serial Data Interface Data Bytes
Input Conditions
Output Frequency
Data Byte 3, Bit 3 = 1
Bit 6
SEL_2
Bit 5
SEL_1
Bit 4
SEL_0
CPU, SDRAM
Clocks (MHz)
PCI Clocks
(MHz)
Spread Percentage
with Spread Spectrum
turned on
0
0
0
68.5
34.25
± 0.5% Center
0
0
1
75
37.5
± 0.5% Center
0
1
0
83.3
41.6
± 0.5% Center
0
1
1
66.8
33.4
± 0.5% Center
1
0
0
103
34.33
± 0.5% Center
1
0
1
112
37.33
± 0.5% Center
1
1
0
133.3
44.43
± 0.5% Center
1
1
1
100
33.3
± 0.5% Center
Table 6. Select Function for Data Byte 3, Bits 0:1
Input Conditions
Output Conditions
Data Byte 3
Function
Normal Operation
Bit 1
Bit 0
CPU0:3
PCI_F, PCI1:7
REF0:2,
IOAPIC0:1
48MHZ
24MHZ
0
0
Note 2
Note 2
14.318 MHz
48 MHz
24 MHz
Test Mode
0
1
X1/2
CPU/2, 3, or 4
X1
X1/2
X1/4
Spread Spectrum On
1
0
Note 2,
55%±0.5
Note 2,
55%±0.5
14.318 MHz
48 MHz
24 MHz
Three-state
1
1
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Hi-Z
Note:
2. CPU and PCI frequency selections are listed in Table 1 and Table 5.
7
PRELIMINARY
W48S101-04
Absolute Maximum Ratings
above those specified in the operating sections of this specification is not implied. Maximum conditions for extended periods may affect reliability.
Stresses greater than those listed in this table may cause permanent damage to the device. These represent a stress rating
only. Operation of the device at these or any other conditions
Parameter
Description
Rating
Unit
V
VDD, VIN
Voltage on any pin with respect to GND
–0.5 to +7.0
–65 to +150
°C
0 to +70
°C
–55 to +125
°C
2 (min.)
kV
TSTG
Storage Temperature
TA
Operating Temperature
TB
Ambient Temperature under Bias
ESDPROT
Input ESD Protection
DC Electrical Characteristics: TA = 0°C to +70°C, VDDQ3 = 3.3V±5%, VDDQ2 = 2.5V±5%
Parameter
Description
Test Condition
Min.
Typ.
Max.
Unit
120
mA
60
mA
Supply Current
IDDQ3
3.3V Supply Current
IDDQ3
2.5V Supply Current
CPUCLK =100 MHz
Outputs Loaded[3]
Logic Inputs
VIL
Input Low Voltage
GND –
0.3
0.8
V
VIH
Input High Voltage
2.0
VDD +
0.3
V
IIL
Input Low Current[4]
–25
µA
IIH
Input High Current[4]
10
µA
IIL
Input Low Current (SEL100/66#)
–5
µA
IIH
Input High Current (SEL100/66#)
5
µA
50
mV
Clock Outputs
VOL
Output Low Voltage
IOL = 1 mA
VOH
Output High Voltage
IOH = –1 mA
3.1
V
VOH
Output High Voltage
IOH = –1 mA
2.2
V
IOL
Output Low Current
IOH
Output High Current
(CPU, APIC)
CPU0:3
VOL = 1.25V
27
57
97
mA
PCI_F, PCI1:7
VOL = 1.5V
20.5
53
139
mA
APIC0:1
VOL = 1.25V
40
85
140
mA
REF0:2
VOL = 1.5V
25
37
76
mA
48MHz 0:1
VOL = 1.5V
25
37
76
mA
CPU0:3
VOL = 1.25V
25
55
97
mA
PCI_F, PCI1:7
VOL = 1.5V
31
55
189
mA
APIC0:1
VOL = 1.25V
40
87
155
mA
REF0:2
VOL = 1.5V
27
44
94
mA
48MHz 0:1
VOL = 1.5V
27
44
94
mA
Notes:
3. All clock outputs loaded with maximum lump capacitance test load specified in the AC Electrical Characteristics section.
4. W48S101-04 logic inputs have internal pull-up devices, except SEL100/66#.
8
PRELIMINARY
W48S101-04
DC Electrical Characteristics: TA = 0°C to +70°C, VDDQ3 = 3.3V±5%, VDDQ2 = 2.5V±5% (continued)
Parameter
Description
Test Condition
Min.
Typ.
Max.
Unit
Crystal Oscillator
VTH
X1 Input Threshold Voltage[5]
1.5
V
CLOAD
Load Capacitance, as seen by
External Crystal[6]
14
pF
CIN,X1
X1 Input Capacitance[7]
28
pF
Pin X2 unconnected
Pin Capacitance/Inductance
CIN
Input Pin Capacitance
COUT
Output Pin Capacitance
6
pF
LIN
Input Pin Inductance
7
nH
Except X1 and X2
5
pF
AC Electrical Characteristics
TA = 0°C to +70°C, VDDQ3 = 3.3V±5%,VDDQ2 = 2.5V± 5%, fXTL = 14.31818 MHz
AC clock parameters are tested and guaranteed over stated operating conditions using the stated lump capacitive load at the
clock output; Spread Spectrum clocking is disabled.
CPU Clock Outputs, CPU0:3 (Lump Capacitance Test Load = 20 pF)
CPU = 66.8 MHz
Parameter
Description
Test Condition/Comments
CPU = 100 MHz
Min. Typ. Max. Min.
15.5
Typ. Max. Unit
tP
Period
Measured on rising edge at 1.25V
15
tH
High Time
Duration of clock cycle above 2.0V
5.2
3.0
ns
tL
Low Time
Duration of clock cycle below 0.4V
5.0
2.8
ns
tR
Output Rise Edge Rate Measured from 0.4V to 2.0V
1
4
1
4
V/ns
tF
Output Fall Edge Rate
Measured from 2.0V to 0.4V
1
4
1
4
V/ns
tD
Duty Cycle
Measured on rising and falling edge at
1.25V
45
55
45
55
%
tJC
Jitter, Cycle-to-Cycle
Measured on rising edge at 1.25V. Maximum difference of cycle time between
two adjacent cycles.
200
250
ps
tSK
Output Skew
Measured on rising edge at 1.25V
175
175
ps
fST
Frequency Stabilization from Power-up
(cold start)
Assumes full supply voltage reached
within 1 ms from power-up. Short cycles
exist prior to frequency stabilization.
3
3
ms
Zo
AC Output Impedance
Average value during switching transition. Used for determining series termination value.
20
10
10.5
20
ns
Ω
Notes:
5. X1 input threshold voltage (typical) is VDD/2.
6. The W48S101-04 contains an internal crystal load capacitor between pin X1 and ground and another between pin X2 and ground. Total load placed on crystal
is 14 pF; this includes typical stray capacitance of short PCB traces to crystal.
7. X1 input capacitance is applicable when driving X1 with an external clock source (X2 is left unconnected).
9
PRELIMINARY
W48S101-04
PCI Clock Outputs, PCI1:7 and PCI_F (Lump Capacitance Test Load = 30 pF
CPU = 66.8/100 MHz
Parameter
Description
Test Condition/Comments
Min.
Typ.
Max.
Unit
tP
Period
Measured on rising edge at 1.5V
30
ns
tH
High Time
Duration of clock cycle above 2.4V
12
ns
tL
Low Time
Duration of clock cycle below 0.4V
12
ns
tR
Output Rise Edge Rate
Measured from 0.4V to 2.4V
1
4
V/ns
tF
Output Fall Edge Rate
Measured from 2.4V to 0.4V
1
4
V/ns
tD
Duty Cycle
Measured on rising and falling edge at 1.5V
45
55
%
tJC
Jitter, Cycle-to-Cycle
Measured on rising edge at 1.5V. Maximum
difference of cycle time between two adjacent cycles.
250
ps
tSK
Output Skew
Measured on rising edge at 1.5V
500
ps
tO
CPU to PCI Clock Skew
Covers all CPU/PCI outputs. Measured on rising
edge at 1.5V. CPU leads PCI output.
4
ns
fST
Frequency Stabilization
from Power-up (cold
start)
Assumes full supply voltage reached within 1 ms
from power-up. Short cycles exist prior to frequency
stabilization.
3
ms
Zo
AC Output Impedance
Average value during switching transition. Used for
determining series termination value.
1.5
Ω
30
APIC0:1 Clock Output (Lump Capacitance Test Load = 20 pF)
CPU = 66.8/100 MHz
Parameter
Description
Test Condition/Comments
Min.
Typ.
Max.
14.31818
Unit
f
Frequency, Actual
Frequency generated by crystal oscillator
MHz
tR
Output Rise Edge Rate
Measured from 0.4V to 2.0V
1
4
V/ns
tF
Output Fall Edge Rate
Measured from 2.0V to 0.4V
1
4
V/ns
tD
Duty Cycle
Measured on rising and falling edge at 1.25V
45
fST
Frequency Stabilization
from Power-up (cold start)
Assumes full supply voltage reached within
1 ms from power-up. Short cycles exist prior to
frequency stabilization.
Zo
AC Output Impedance
Average value during switching transition. Used
for determining series termination value.
55
%
1.5
ms
Ω
15
REF0:2 Clock Output (Lump Capacitance Test Load = 20 pF)
CPU = 66.8/100 MHz
Parameter
Description
Test Condition/Comments
Min.
Typ.
Max.
Frequency, Actual
Frequency generated by crystal oscillator
tR
Output Rise Edge Rate
Measured from 0.4V to 2.4V
0.5
2
V/ns
tF
Output Fall Edge Rate
Measured from 2.4V to 0.4V
0.5
2
V/ns
tD
Duty Cycle
Measured on rising and falling edge at 1.5V
45
55
%
fST
Frequency Stabilization from
Power-up (cold start)
Assumes full supply voltage reached within
1 ms from power-up. Short cycles exist prior to
frequency stabilization.
3
ms
Zo
AC Output Impedance
Average value during switching transition. Used
for determining series termination value.
10
14.318
Unit
f
40
MHz
Ω
PRELIMINARY
W48S101-04
48MHz0:1 Clock Output (Lump Capacitance Test Load = 20 pF = 66.6/100 MHz)
CPU = 66.8/100 MHz
Parameter
f
Description
Frequency, Actual
Test Condition/Comments
Min.
Determined by PLL divider ratio (see m/n below)
Typ.
Max.
Unit
48.008
MHz
ppm
fD
Deviation from 48 MHz
(48.008 – 48)/48
+167
m/n
PLL Ratio
(14.31818 MHz x 57/17 = 48.008 MHz)
57/17
tR
Output Rise Edge Rate
Measured from 0.4V to 2.4V
0.5
2
V/ns
tF
Output Fall Edge Rate
Measured from 2.4V to 0.4V
0.5
2
V/ns
tD
Duty Cycle
Measured on rising and falling edge at 1.5V
45
55
%
fST
Frequency Stabilization
from Power-up (cold start)
Assumes full supply voltage reached within 1 ms
from power-up. Short cycles exist prior to frequency stabilization.
3
ms
Zo
AC Output Impedance
Average value during switching transition. Used
for determining series termination value.
Ordering Information
Ordering Code
W48S101
Freq. Mask
Code
Package
Name
-04
H
Package Type
48-pin SSOP (300 mils)
Document #: 38-00853
11
40
Ω
PRELIMINARY
W48S101-04
Package Diagram
48-Pin Small Shrink Outline Package (SSOP, 300 mils)
Summary of nominal dimensions in inches:
Body Width: 0.296
Lead Pitch: 0.025
Body Length: 0.625
Body Height: 0.102
© Cypress Semiconductor Corporation, 1999. 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.