SPECTRALINEAR CY28342ZC

CY28342
High-performance SiS645/650 Pentium® 4-Clock Synthesizer
Features
• Supports Pentium£ 4-type CPUs
• SMBus support with read-back capabilities
• 3.3V power supply
• Spread Spectrum EMI reduction
• Eight copies of PCI clocks
• Dial-a-Frequency® features
• One 48 MHz USB clock
• Dial-a-Ratio™ features
• Two copies of ZCLK clocks
• Dial-a-dB® features
• One 48 MHz/24MHz programmable SIO clock
• 48-pin SSOP and TSSOP packages
• Two differential CPU clock pairs
• Watchdog Function
XIN
XOUT
REF(0:2)
CPU(0:1)T
CPU(0:1)C
PLL1
CPU_STP#
SDCLK
IREF
FS(0:4)
MULT0
AGP(0:1)
Power
on
Latch
VTTPWRGD
ZCLK(0:1)
/2
PCI_STP#
PCI(0:5)
PCI_F(0:1)
PLL2
48M
48M_24M#
PD#
WD
Logic
SDATA
SCLK
I2C
Logic
SRESET#
VDDR
**FS0/REF0
**FS1/REF1
**FS2/REF2
VSSR
XIN
XOUT
VSSZ
ZCLK0
ZCLK1
VDDZ
*SRESET#/PCI_STP#
VDDP
**FS3/PCI_F0
**FS4/PCI_F1
PCI0
PCI1
VSSP
VDDP
PCI2
PCI3
PCI4
PCI5
VSSP
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
CY28342
Pin Configuration[1]
Block Diagram
48
47
46
45
44
43
42
41
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
VDDSD
SDCLK
VSSSD
CPU_STP#*
CPU1T
CPU1C
VDDC
VSSC
CPU0T
CPU0C
IREF
VSSA
VDDA
SCLK
SDATA
PD#/VTTPWRGD*
VSSAGP
AGP0
AGP1
VDDAGP
VDD48M
48M
24_48M/MULT0*
VSS48M
48 Pin SSOP andf TSSOP
Note:
1. Pins marked with [*] have internal pull-up resistors. Pins marked with [**] have internal pull-down resistors.
Rev 1.0, November 20, 2006
2200 Laurelwood Road, Santa Clara, CA 95054
Page 1 of 21
Tel:(408) 855-0555
Fax:(408) 855-0550
www.SpectraLinear.com
CY28342
Table 1. Frequency Table
FS(4:0)
CPU (MHz)
SDRAM (MHz)
ZCLK (MHz)
AGP (MHz)
PCI (MHz)
VCO (MHz)
00000
100.20
100.20
66.80
66.80
33.40
400.8
00001
133.45
133.45
66.73
66.73
33.365
533.8
00010
100.20
133.60
66.80
66.80
33.40
400.8
00011
133.45
100.09
66.73
66.73
33.365
400.4
00100
100.20
167.00
62.63
62.63
31.315
501.0
00101
133.33
166.66
66.67
66.67
33.335
666.7
00110
100.20
150.30
66.80
66.80
33.40
601.2
00111
133.33
66.67
66.67
66.67
33.335
533.3
01000
100.20
120.24
66.80
66.80
33.40
601.2
01001
145.00
145.00
64.44
64.44
32.22
580.0
01010
111.11
133.33
66.67
66.67
33.335
666.7
01011
166.60
133.28
66.64
66.64
32.22
666.4
01100
66.80
66.80
66.80
66.80
33.40
400.8
01101
66.80
66.80
50.10
50.10
25.05
400.8
01110
100.20
133.60
100.20
66.80
33.40
400.8
01111
100.20
133.60
80.16
66.80
33.40
400.8
10000
100.20
167.00
83.50
62.63
31.315
501.0
10001
100.20
167.00
100.20
62.63
31.315
501.0
10010
102.20
136.27
68.13
68.13
34.065
408.8
10011
133.40
200.10
66.70
66.70
33.35
400.2
10100
105.00
140.00
70.00
70.00
35.00
420.0
10101
83.33
138.89
69.44
69.44
34.72
416.6
10110
108.00
144.00
72.00
72.00
36.00
432.0
10111
83.33
104.16
69.44
69.44
34.72
416.6
11000
116.00
145.00
64.44
64.44
32.22
580.0
11001
83.33
166.67
62.50
62.50
31.25
500.0
11010
120.00
150.00
66.67
66.67
33.335
600.0
11011
95.00
142.50
63.33
63.33
31.665
570.0
11100
112.00
140.00
62.22
62.22
31.11
560.0
11101
75.00
125.00
62.50
62.50
31.25
375.0
11110
108.00
180.00
67.50
67.50
33.75
540.0
11111
95.00
158.33
79.17
79.17
39.585
475.0
Rev 1.0, November 20, 2006
Page 2 of 21
CY28342
Pin Description
[2]
Pin
Name
6
XIN
7
XOUT
39,40,43,44
PWR
I/O
Description
I
Oscillator buffer input. Connect to a crystal or to an external clock.
VDDR
O
Oscillator buffer output. Connect to a crystal. Do not connect when
an external clock is applied at XIN.
CPU (0:1)T,
CPU (0:1)C
VDDC
O
Differential host output clock pairs. See Table 1 for frequencies and
functionality.
16,17,20,23
PCI (0:5)
VDDP
O
PCI clock outputs. See Table 1.
14
FS3/PCI_F0
VDDP
I/O
PD
Power-on bidirectional Input/Output (I/O). At power-up, FS3 is the
input. When VTTPWRGD transitions to a logic HIGH, FS3 state is
latched and this pin becomes PCI_F0 clock output. See Table 1.
15
FS4/PCI_F1
VDDP
I/O
PD
Power-on bidirectional I/O. At power-up, FS4 is the input. When
VTTPWRGD transitions to a logic HIGH, FS4 state is latched and this
pin becomes PCI_F1 Clock Output. See Table 1.
2
FS0/REF0
VDDR
I/O
PD
Power-on bidirectional I/O. At power-up, FS0 is the input. When
VTTPWRGD transitions to a logic HIGH, FS0 state is latched and this
pin becomes REF0, buffered Output copy of the device’s XIN clock.
3
FS1/REF1
VDDR
I/O
PD
Power-on bidirectional I/O. At power-up, FS1 is the input. When
VTTPWRGD is transited to logic LOW, FS1 state is latched and this pin
becomes REF1, buffered Output copy of the device’s XIN clock.
4
FS2/REF2
VDDR
I/O
PD
Power-on bidirectional I/O. At power-up, FS2 is the input. When
VTTPWRGD is transited to logic LOW, FS2 state is latched and this pin
becomes REF2, buffered Output copy of the device’s XIN clock.
38
IREF
I
Current reference programming input for CPU buffers. A resistor is
connected between this pin and VSS. See Figure 8.
33
PD#/VTTPR
GD
I
PU
Power-down input/VTT power good input. At power-up, VTTPWRGD
is the input. When this input is transitions initially from LOW to HIGH,
the FS (0:4) and MULT0 are latched. After the first LOW-to-HIGH
transition, this pin becomes a PD# input with an internal pull-up. When
PD# is asserted LOW, the device enters power-down mode. See power
management function.
27
48M
VDD48M
O
26
24_48M/MUL
T0
VDD48M
I/O
PU
9,10
ZCLK (0:1)
VDDZ
O
HyperZip Clock Outputs. See Table 1.
34
SDATA
I/O
Serial Data Input. Conforms to the SMBus specification of a Slave
Receive/Transmit device. It is an input when receiving data, and an open
drain output when acknowledging or transmitting data.
35
SCLK
I
Serial Clock Input. Conforms to the SMBus specification.
12
SRESET#
O
PCI Clock Disable Input. If Byte12 Bit7 = 0, this pin becomes an
SRESET# open drain output, and the internal pull-up is not active. See
system reset description.
PCI_STP#
I
PU
System Reset Control Output. If Byte12 Bit7 = 1 (Default), this pin
becomes PCI Clock Disable Input. When PCI_STP# is asserted LOW,
PCI (0:5) clocks are synchronously disabled in a LOW state. This pin
does not affect PCI_F (0:1) if they are programmed to be free-running
clocks via the device’s SMBus interface.
CPU_STP#
I
PU
CPU Clock Disable Input. When asserted LOW, CPU (0:1)T clocks are
synchronously disabled in a HIGH state and CPU (0:1)C clocks are
synchronously disabled in a LOW state.
45
Rev 1.0, November 20, 2006
Fixed 48-MHz USB clock output.
Power-on bidirectional I/O. At power-up, MULT0 is the input. When
VTTPWRGD is transitions to logic HIGH MULT0 state is latched and this
pin becomes 24_48M, SIO programmable clock output.
Page 3 of 21
CY28342
Pin Description (continued)[2]
Pin
Name
PWR
I/O
Description
47
SDCLK
VDDSD
O
SDRAM Clock Output.
30,31
AGP (0:1)
VDDAGP
O
AGP Clock Outputs. See Table 1 for frequencies and functionality.
48
VDDSD
PWR
3.3V power supply for SDRAM clock output.
29
VDDAGP
PWR
3.3V power supply for AGP clock output.
11
VDDZ
PWR
3.3V power supply for HyperZip clock output.
1
VDDR
PWR
3.3V power supply for REF clock output.
13,19
VDDP
PWR
3.3V power supply for PCI clock output.
42
VDDC
PWR
3.3V power supply for CPU clock output.
28
VDD48M
PWR
3.3V power supply for 48-MHz/24-MHz clock output.
36
VDDA
PWR
3.3V analog power supply.
18,24
VSSP
PWR
GND for PCI clocks outputs.
41
VSSC
PWR
GND for CPU clocks outputs.
8
VSSZ
PWR
GND for HyperZip clocks outputs.
25
VSS48M
PWR
GND for 48-MHz/24-MHz clocks outputs.
5
VSSR
PWR
GND for REF clocks outputs.
46
VSSSD
PWR
GND for SDRAM clocks outputs.
32
VSSAGP
PWR
GND for AGP clocks outputs.
37
VSSA
PWR
GND for analog.
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, etc., can be individually
enabled or disabled.
The clock driver serial protocol accepts byte Write, byte Read,
block Write, and block Read operations from the controller. For
a 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 individual indexed bytes. The
offset of the indexed byte is encoded in the command code,
as described in Table 2.
The registers associated with the SDI initializes to their default
setting upon power-up, and therefore the 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 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).
Note:
2. PU = Internal pull-up. PD = internal pull-down. T = Tri-level logic input with valid logic voltages of LOW = < 0.8V, T = 1.0 –1.8V, and HIGH = > 2.0V.
Rev 1.0, November 20, 2006
Page 4 of 21
CY28342
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 operations. 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
Block Read Protocol
Bit
Start
1
Slave address – 7 bits
2:8
Description
Start
Slave address – 7 bits
9
Write
9
Write
10
Acknowledge from slave
10
Acknowledge from slave
11:18
19
20:27
28
29:36
37
38:45
Command code – 8-bit “00000000” stands for
block operation
11:18
Command code – 8-bit “00000000” stands for
block operation
Acknowledge from slave
19
Acknowledge from slave
Byte count –8 bits
20
Repeat start
Acknowledge from slave
Data byte 0 – 8 bits
Acknowledge from slave
Data byte 1 – 8 bits
46
Acknowledge from slave
....
Data byte N/slave acknowledge...
....
Data byte N – 8 bits
....
Acknowledge from slave
....
Stop
21:27
Slave address – 7 bits
28
Read
29
Acknowledge from slave
30:37
38
39:46
47
48:55
Byte count from slave – 8 bits
Acknowledge
Data byte from slave – 8 bits
Acknowledge
Data byte from slave – 8 bits
56
Acknowledge
....
Data bytes from slave/acknowledge
....
Data byte N from slave – 8 bits
....
Not acknowledge
....
Stop
Table 4. Byte Read and Byte Write Protocol
Byte Write Protocol
Bit
1
2:8
Description
Start
Slave address – 7 bits
Byte Read Protocol
Bit
1
2:8
Description
Start
Slave address – 7 bits
9
Write
9
Write
10
Acknowledge from slave
10
Acknowledge from slave
11:18
19
20:27
Command Code – 8 bit “1xxxxxxx” stands for
byte operation bit[6:0] of the command code
represents the offset of the byte to be accessed
Acknowledge from slave
Byte count – 8 bits
28
Acknowledge from slave
29
Stop
Rev 1.0, November 20, 2006
11:18
Command Code – 8-bit “1xxxxxxx” stands for
byte operation bit[6:0] of the command code
represents the offset of the byte to be accessed
19
Acknowledge from slave
20
Repeat start
21:27
Slave address – 7 bits
28
Read
29
Acknowledge from slave
Page 5 of 21
CY28342
Table 4. Byte Read and Byte Write Protocol (continued)
Byte Write Protocol
Bit
Byte Read Protocol
Description
Bit
Description
30:37
Data byte from slave – 8 bits
38
Not acknowledge
39
Stop
Since SDR and DDR Zero Delay Buffers will share this same address, the device starts from Byte 4.
Byte 4: CPU Clock Register (All bits are Read and Write functional)
Bit
@Pup
Pin#
Name
7
H/W Setting
14
FS3
For selecting frequencies in Table 1.
6
H/W Setting
4
FS2
For selecting frequencies in Table 1.
5
H/W Setting
3
FS1
For selecting frequencies in Table 1.
4
H/W Setting
2
FS0
For selecting frequencies in Table 1.
15
FS4
For selecting frequencies in Table 1.
3
0
2
H/W Setting
1
1
0
0
Description
0 = HW, 1 = SW frequency selection.
SSCG
Spread Spectrum Enable. 0 = spread off, 1 = spread on.
This is a Read and Write control bit.
Master output control 0 = running, 1 = three-state all outputs.
Byte 5: CPU Clock Register (all bits are Read-only)
Bit
7
@Pup
0
Pin#
Name
Description
Reserved.
6
0
5
X
26
MULT0
Reserved.
4
X
15
FS4
FS4 Read-back. This bit is Read-only.
3
X
14
FS3
FS3 Read-back. This bit is Read-only.
2
X
4
FS2
FS2 Read-back. This bit is Read-only.
1
X
3
FS1
FS1 Read-back. This bit is Read-only.
0
X
2
FS0
FS0 Read-back. This bit is Read-only.
MULT0 (pin 26) value. This bit is Read-only.
Byte 6: CPU Clock Register (All bits are Read and Write functional)
Bit
@Pup
7
0
Pin#
Name
Description
6
0
5
0
14
PCI_F0
PCI_STP# control of PCI_F0. 0 = free running, 1 = stopped when PCI_STP# is LOW.
4
0
15
PCI_F1
PCI_STP# control of PCI_F1. 0 = free running, 1 = stopped when PCI_STP# is LOW.
Function Test Bit. Always program to 0.
Reserved.
3
1
40,39
Controls CPU0T and CPU0C functionality when CPU_STP# is asserted LOW.
CPU0T/C 0 = free running, 1 = stopped with CPU_STP# asserted LOW.
This is a Read and Write control bit.
2
0
44,43
Controls CPU1T and CPU1C functionality when CPU_STP# is asserted LOW
CPU1T/C 0= Free Running, 1 Stopped with CPU_STP# asserted to LOW.
This and Read and Write control bit.
1
1
40,39
CPU0T/C
CPU0T, CPU0C output control, 1= enabled, 0 = disabled.
This is a Read and Write control bit.
0
1
44,43
CPU1T/C
CPU1T, CPU1C output control, 1= enabled, 0 = disabled.
This is a Read and Write control bit.
Rev 1.0, November 20, 2006
Page 6 of 21
CY28342
Byte 7: PCI Clock Register (All bits are Read and Write functional)
Bit
@Pup
Pin#
Name
7
1
15
PCI_F0
6
1
14
PCI_F1
5
1
23
PCI5
Description
PCI_F0 output control 1 = enabled, 0 = forced LOW.
PCI_F1 output control 1 = enabled, 0 = forced LOW.
PCI5 output control 1 = enabled, 0 = forced LOW.
4
1
22
PCI4
PCI4 output control 1 = enabled, 0 = forced LOW.
3
1
21
PCI3
PCI3 output control 1 = enabled, 0 = forced LOW.
2
1
20
PCI2
PCI2 output control 1 = enabled, 0 = forced LOW.
1
1
17
PCI1
PCI1 output control 1 = enabled, 0 = forced LOW.
0
1
16
PCI0
PCI0 output control 1 = enabled, 0 = forced LOW.
Byte 8: Silicon Signature Register (all bits are Read-only)
Bit
@Pup
7
1
6
0
5
0
4
0
3
0
2
0
1
0
0
0
Description
Vendor ID
1000 = Cypress
Revision ID
Byte 9: Peripheral Control Register (All bits are Read and Write)
Bit
@Pup
Pin#
Name
Description
7
1
33
PD#
6
0
5
1
27
48M
4
1
26
48M_24M
48M_24M output control 1 = enabled, 0 = forced LOW.
3
0
26
48M_24M
48M_24M, 0 = pin 26 output is 24MHz, 1= pin 28 output is 48 MHz.
2
0
SS2 Spread Spectrum control bit (0= down spread, 1= center spread).
1
0
SS1 Spread Spectrum control bit. See Table 10.
0
0
SS0 Spread Spectrum control bit. See Table 10.
PD# Enable. 0 = enable, 1 = disable.
0 = when PD# asserted LOW, CPU(0:1)T stop in a high state, CPU(0:1)C stop in
a LOW state. 1 = when PD# asserted LOW, CPU(0:1)T and CPU(0:1)C stop in H-Z.
48M output control 1 = enabled, 0 = forced LOW.
Byte 10: Peripheral Control Register (All bits are Read and Write functional)
Bit
@Pup
Pin#
Name
7
1
47
SDCLK
6
1
4
REF2
REF2 output control 1 = enabled, 0 = forced LOW.
5
1
3
REF1
REF1 output control 1 = enabled, 0 = forced LOW.
4
1
2
REF0
REF0 output control 1 = enabled, 0 = forced LOW.
3
1
10
ZCLK1
ZCLK1 output enable 1 = enabled, 0 = disabled.
2
1
9
ZCLK0
ZCLK0 output enabled 1 = enabled, 0 = disabled.
1
1
30
AGP1
AGP1 output enabled 1 = enabled, 0 = disabled.
0
1
31
AGP0
AGP0 output enabled 1 = enabled, 0 = disabled.
Rev 1.0, November 20, 2006
Description
SDCLK output enable 1 = enabled, 0 = disabled.
Page 7 of 21
CY28342
Byte 11: Dial-a-Skew™ and Dial-a-Ratio™ Control Register (All bits are Read and Write functional)
Bit
@Pup
7
0
6
0
DARSD2 Programming these bits allows modifying the frequency ratio of the SDCLK clock relative to the VCO.
DARSD1 See Table 5.
Name
Description
5
0
DARSD0
4
0
3
0
DARAG2 Programming these bits allows modifying the frequency ratio of the AGP(1:0), PCI(5:0) and PCIF(0:1)
DARAG1 clocks relative to the VCO. See Table 6.
2
0
DARAG0
1
0
DASSD1 Programming these bits allows shifting skew between CPU and SDCLK signals. See Table 7.
0
0
DASSD0
Table 5. Dial-a-Ratio SDCLK
DARSD (2:0)
VC0/SDCLK ratio
000
Frequency selection default
001
2
010
3
011
4
100
5
101
6
110
8
111
9
Table 6. Dial-a-Ratio AGP(0:1)[3]
DARAG (2:0)
VC0/AGP Ratio
000
Frequency selection default
001
6
010
7
011
8
100
9
101
10
110
10
111
10
Table 7. Dial-a-Skew SDCLK CPU
DASSD (1:0)
SDCLK-CPU Skew
00
0 ps (default)[4]
01
+150 ps (CPU lag)*
10
+300 ps (CPU lag)*
11
+450 ps (CPU lag)*
Notes:
3. The ratio of AGP to PCI is retained at 2:1.
4. See Figure 8 for CPU measurement point. See Figure 9 for SDCLK measurement point.
Rev 1.0, November 20, 2006
Page 8 of 21
CY28342
Byte 12: Watchdog Time Stamp Register (All bits are Read and Write functional)
Bit
@Pup
Name
Description
7
1
SRESET#/PCI_STP#. 1 = pin 12 is the input pin as PCI_STP# signal. 0 = pin 12 is the output pin
as SRESET# signal.
6
0
Frequency Revert. 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).
5
0
WDTEST. For WD-Test, ALWAYS program to “0.”
4
0
WD Alarm. 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
These bits select the Watchdog Time Stamp Value. See Table 8.
Table 8. Watchdog Time Stamp Table
WD(3:0)
FUNCTION
0000
Off
0001
1 second
0010
2 seconds
0011
3 seconds
0100
4 seconds
0101
5 seconds
0110
6 seconds
0111
7 seconds
1000
8 seconds
1001
9 seconds
1010
10 seconds
1011
11 seconds
1100
12 seconds
1101
13 seconds
1110
14 seconds
1111
15 seconds
Byte 13: Dial-a-Frequency Control Register N (All bits are Read and Write functional)[5]
Bit
@Pup
Description
7
0
Reserved.
6
0
N6, MSB
5
0
N5
4
0
N4
3
0
N3
2
0
N2
1
0
N3
0
0
N0, LSB
Note:
5. Byte 13 and Byte 14 should be Write together in every case.
Rev 1.0, November 20, 2006
Page 9 of 21
CY28342
Byte 14: Dial-a-Frequency Control Register (All bits are Read and Write functional)[5]
Bit
@Pup
7
0
Reserved.
Description
6
0
R5 MSB
5
0
R4
4
0
R3
3
0
R2
2
0
R1
1
0
R0, LSB
0
0
R and N Register Load Gate. 0 = gate closed (data is latched), 1= gate open (data is loading
from SMBus registers into R and N)#.
Dial-a-Frequency Feature
Spread Spectrum Clock Generation (SSCG)
SMBus Dial-a-Frequency feature is available in this device via
byte 13 and byte 14. P is a large-value, phase-locked loop
(PLL) constant that depends on the frequency selection
achieved through the hardware selectors FS(4:0). P value
may be determined from the following table.
Spread Spectrum is a modulation technique used to minimize
electromagnetic interference (EMI) radiation generated by
repetitive digital signals. A clock presents the greatest EMI
energy at the center of the frequency it is generating. Spread
Spectrum distributes this energy over a specific and controlled
frequency bandwidth, thereby causing the average energy at
any one point in this band to decrease in value. This technique
is achieved by modulating the clock away from its resting
frequency by a certain percentage (which also determines the
amount of EMI reduction). In this device, Spread Spectrum is
enabled by setting specific register bits in the SMBus control
bytes. See the SMBus register section of this data sheet for
the exact bit and byte functionally. The following table is a
listing of the modes and percentages of Spread Spectrum
modulation that this device incorporates.
Table 9.
FS(4:0)
P
00000, 00001, 00010, 00111, 01001, 01011,
01110, 01111, 10010, 10100, 10110
95996900
00100, 00101, 10000, 10001, 10101, 10111,
11000, 11010, 11100, 11101, 11110, 11111
76797520
00110, 01000, 01010, 01100, 01101, 11001,
11011
63997933
00011, 10011
127995867
Rev 1.0, November 20, 2006
Table 10.Spread Spectrum
SS2
SS1
SS0
Spread Mode
Spread%
0
0
0
Down
0, –0.50
0
0
1
Down
+0.12, –0.62
0
1
0
Down
+0.25, –0.75
0
1
1
Down
+0.50, –1.00
1
0
0
Center
+0.25, –0.25
1
0
1
Center
+0.37, –0.37
1
1
0
Center
+0.50, –0.50
1
1
1
Center
+0.75, –0.75
Page 10 of 21
CY28342
System Self-recovery Clock Management
Watchdog times out, this device will keep operating in its
normal condition with the new selected frequency. If the
Watchdog times out the first time before the new SMBus reprograms byte 12, bits(3:0) to (0000), then this device will send
a low system reset pulse, on SRESET# (see byte 12, bit 7),
and changes the Watchdog alarm (byte 12, bit 4) status to “1”
then restarts the Watchdog timer. If the Watchdog times out
a second time, this device will send another low pulse on
SRESET#, will relatch original hardware strapping frequency
(or second-to-last software-selected frequency, see byte 12,
bit6) selection, set Watchdog alarm bit (byte 12, bit4) to “1,”
then start the Watchdog timer again. The above-described
sequence will keep repeating until the BIOS clears the SMBus
byte 12 bits(3:0). Once the BIOS sets byte 12 bits(3:0) = 0000,
the Watchdog timer is turned off and the Watchdog alarm bit
(byte 12, bit 4) is reset to “0.”
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 byte 4 or through bytes 13 and
14, it must have previously sent a command selecting which
time-out stamp the Watchdog must perform to byte 12, or 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 new frequency. If this device
receives a new SMBus command to clear the bits originally
programmed in byte 12, bits(3:0) (reprogram to 0000) before
S y s t e m r u n n in g w it h
o r ig in a lly s e le c t e d
f r e q u e n c y v ia
h a r d w a r e s t r a p p in g .
N o
F r e q u e n c y w ill c h a n g e b u t S y s t e m S e lf
R e c o v e r y n o t a p p lic a b le ( n o t im e s t a m p
s e le c t e d a n d b y t e 1 2 , b it ( 3 : 0 ) is s t ill =
"0 0 0 0 "
R e c e iv e F r e q u e n c y
C h a n g e R e q u e s t v ia
S M B u s B y t e 4 o r V ia D ia la -fre q u e n c y ?
Y es
C h a n g e to a n e w
fre q u e n c y
N o
Is S M B u s B y te 9 , tim e o u t
s t a m p e n a b le d - ( b y t e 1 2 , b it
(3 :0 )
0 0 0 0 )?
Y es
1 ) S e n d a n o th e r 3 m S lo w p u ls e o n S R E S E T
2 ) R e la t c h o r ig in a l h a r d w a r e s t r a p p in g s e le c t io n
f o r r e t u r n t o o r ig in a l f r e q u e n c y s e t t in g s .
3 ) S e t W D A la r m b it ( b y t e 1 2 , B it 4 ) t o " 1 "
4 ) S ta r t W D tim e r
S t a r t in t e r n a l w a t c h d o g t im e r .
Y es
W a t c h D o g t im e o u t ?
1) S end S R E S ET
p u ls e
2 ) S e t W D b it
( b y t e 1 2 , b it 4 ) t o '1 '
3 ) S t a r t W D t im e r
Y es
W a t c h D o g t im e o u t ?
N o
N o
S M B u s b y te 1 2 tim e
o u t s t a m p d is a b le d ?
S M B u s b y te 9 tim e o u t
s t a m p d is a b le d , B y t e
1 2 , b it ( 3 : 0 ) = ( 0 0 0 0 ) ?
N o
N o
Yes
Y es
T u r n o ff w a tc h d o g tim e r .
K e e p n e w f r e q u e n c y s e t t in g . S e t W D a la r m
b it ( b y t e 1 2 , b it 4 ) t o ''0 '
Table 11.CPU Clock Current Select Function
Mult0
Board Target Trace/Term Z
Reference R, Iref – VDD (3*Rr)
Output Current
Voh @ Z
0
50 Ohms (not used)
Rr = 221 1%, Iref = 5.00mA
IOH = 4*Iref
1.0V @ 50
1
50 Ohms
Rr = 475 1%, Iref = 2.32mA
IOH = 6*Iref
0.7V @ 50
Table 12.Group Timing Relationship and Tolerances
Offset
Tolerance(or Range)
Conditions
Notes
CPU to SDCLK
Typical 0 ns
±2 ns
CPU leads
Note 6
CPU to AGP
Typical 2 ns
1-4ns
CPU leads
Note 6
CPU to ZCLK
Typical 2 ns
1-4ns
CPU leads
Note 6
CPU to PCI
Typical 2 ns
1-4ns
CPU leads
Note 6
Rev 1.0, November 20, 2006
Page 11 of 21
CY28342
Table 12.Group Timing Relationship and Tolerances
Note:
6. See Figure 8 for CPU clock-measurement point. See Figure 9 for SDCLK, AGP, ZCLK and PCI output-measurement points.
Rev 1.0, November 20, 2006
Page 12 of 21
CY28342
The CPU_STP# signal is an active LOW input used for
synchronous stopping and starting of the CPU output clocks
while the rest of the clock generator continues to function.
is driven HIGH with a current value equal to (Mult0
“select”) × (Iref), and the CPU# signal will not be driven. Due
to external pull-down circuitry, CPU# will be LOW during this
stopped state.
CPU_STP# Assertion
CPU_STP# Deassertion
When CPU_STP# pin is asserted, all CPU outputs that are set
with the SMBus configuration to be stoppable via assertion of
CPU_STP# will be stopped after being sampled by two falling
CPU clock edges. The final state of the stopped CPU signals
is CPU = HIGH and CPU0# = LOW. There is no change to the
output drive current values during the stopped state. The CPU
The deassertion of the CPU_STP# signal will cause all CPU
outputs that were stopped to resume normal operation in a
synchronous manner. Synchronous manner meaning that no
short or stretched clock pulses will be produce when the clock
resumes. The maximum latency from the deassertion to active
outputs is no more than two CPU clock cycles.
CPU_STP# Clarification
CPU_STP#
CPUT
CPUC
Figure 1. Assertion CPU_STP# Waveform
CPU_STP#
CPUT
CPUC
CPUT
CPUC
Figure 2. Deassertion CPU_STP# Waveform
Rev 1.0, November 20, 2006
Page 13 of 21
CY28342
PCI_STP# Assertion
The PCI_STP# signal is an active LOW input used for
synchronous stopping and starting the PCI outputs while the
rest of the clock generator continues to function. The set-up
time for capturing PCI_STP# going LOW is 10 ns (tsetup). (See
Figure 3.) The PCI_F (0:2) clocks will not be affected by this
pin if their control bits in the SMBus register are set to allow
them to be free running.
PCI_STP# Deassertion
The deassertion of the PCI_STP# signal will cause all PCI(0:6)
and stoppable PCI_F(0:2) clocks to resume running in
a synchronous manner within two PCI clock periods after
PCI_STP# transitions to a high level.
t setup
PCI_STP#
PCI_F(0:2) 33M
PCI(0:6) 33M
Figure 3. Assertion PCI_STP# Waveform
t setup
PCI_STP#
PCI_F(0:2)
PCI(0:6)
Figure 4. Deassertion PCI_STP# Waveform[7]
Note:
7. The PCI STOP function is controlled by 2 inputs. One is the device PCI_STP# pin number 34 and the other is SMBus byte 0 bit 3. These 2 inputs are logically
ANDed. If either the external pin or the internal SMBus register bit is set low then the stoppable PCI clocks will be stopped in a logic low state. Reading SMBus
Byte 0 Bit 3 will return a 0 value if either of these control bits are set LOW thereby indicating the device’s stoppable PCI clocks are not running.
Rev 1.0, November 20, 2006
Page 14 of 21
CY28342
PD# (Power-Down) Clarification
PD# - Assertion (transition from logic “l” to logic “0”)
The PD# (power-down) pin is used to shut off ALL clocks prior
to shutting off power to the device. PD# is an asynchronous
active LOW input. This signal is synchronized internally to the
device powering down the clock synthesizer. PD# is an
asynchronous function for powering up the system. When PD#
is low, all clocks are driven to a LOW value and held there and
the VCO and PLLs are also powered down. All clocks are shut
down in a synchronous manner so has not to cause glitches
while transitioning to the low “stopped” state.
When PD# is sampled LOW by two consecutive rising edges
of CPUC clock then all clock outputs (except CPUT) clocks
must be held LOW on their next HIGH-to-LOW transition.
CPUT clocks must be hold with CPUT clock pin driven HIGH
with a value of 2x Iref and CPUC undriven.
Due to the state of the internal logic, stopping and holding the
REF clock outputs in the LOW state may require more than
one clock cycle to complete.
PD# Deassertion (transition from logic “0” to logic “1”)
The power-up latency between PD# rising to a valid logic “1”
level and the starting of all clocks is less than 3.0 ms.
PD #
C PU (0:1)T
C PU (0:1)C
C PU Internal
C PU # Internal
Figure 5. Power-down Assertion/Deassertion Timing Waveforms – Nonbuffered Mode
VID (0:3),
SEL (0,1)
VTTPWRGD
PWRGD
0.2-0.3mS
Delay
VDD Clock Gen
Clock State
Clock Outputs
Clock VCO
State 0
Wait for
VTT_GD#
State 1
Sample Sels
State 2
Off
Off
State 3
On
(Note A)
On
Figure 6. VTTPWRGD Timing Diagram[8]
Note:
8. Device is not affected; VTTPWRGD is ignored.
Rev 1.0, November 20, 2006
Page 15 of 21
TP
W
= H RG
ig h D
CY28342
VT
S1
D e la y 0 .25 m S
S2
S a m p le
In p u ts
F S (3 :0 )
W a it fo r
1 .1 4 6 m s
E n a b le
O
u tpu te s
Outputs
V D D A = 2 .0 V
S0
S3
P o w er O ff
N o rm a l
O p e ra tio n
V D D 3.3 = O ff
Figure 7. Clock Generator Power-up/Run State Diagram
Rev 1.0, November 20, 2006
Page 16 of 21
CY28342
Maximum Ratings
Storage Temperature:..................................–65qC to +150qC
Input Voltage Relative to VSS................................VSS – 0.3V
Input Voltage Relative to VDDQ or AVDD: ............. VDD + 0.3V
Operating Temperature: ....................................0qC to +70qC
Maximum Power Supply: ............................................... 3.5V
DC Characteristics
Current Accuracy[9]
Conditions
Configuration
Load
Min.
Max.
Iout
VDD = nominal (3.30V)
M0= 0 or 1 and Rr shown in table
Nominal test
load for given
configuration
–7% Inom
+7% Inom
Iout
VDD = 3.30 ±5%
All combinations of M0 or 1 and Rr
shown in table
Nominal test
load for given
configuration
–12% Inom
+12% Inom
DC Component Parameters (VDD =3.3V±5%, TA = 0°C to 70°C)
Parameter
Description
Min.
Typ.
Max.
Units
Conditions
280
mA
All frequencies at maximum values[10]
Note 11
mA
PD# Asserted
Idd3.3V
Dynamic Supply Current
Ipd3.3V
Power-down Supply Current
Cin
Input Pin Capacitance
5
pF
Cout
Output Pin Capacitance
6
pF
Lpin
Pin Inductance
7
nH
Cxtal
Crystal Pin Capacitance
42
pF
30
36
Measured from the XIN or XOUT Pin to
Ground
AC Parameters
100 MHz
Parameter
Description
Min.
Max.
133 MHz
Min.
Max.
Unit
Notes
Crystal
TDC
XIN Duty Cycle
47.5
52.5
47.5
52.5
%
12,13
TPeriod
XIN period
69.841
71.0
69.841
71.0
ns
12,13,14,15
VHIGH
XIN HIGH Voltage
0.7VDD
VDD
0.7VDD
VDD
V
VLOW
XIN LOW Voltage
0
0.3VDD
0
0.3VDD
V
Tr/Tf
XIN Rise and Fall Times
10.0
10.0
ns
TCCJ
XIN Cycle to Cycle Jitter
500
500
ps
13,14,16
CPU at 0.7V Timing
TSKEW
Any CPU to CPU Clock Skew
150
150
ps
16, 17, 18
TCCJ
150
150
ps
16, 17, 18
CPU Cycle to Cycle Jitter
TDC
CPU and CPUC Duty Cycle
45
55
45
55
%
16, 17, 18
TPeriod
CPU and CPUC Period
9.8
10.2
7.35
7.65
ns
16, 17, 18
Notes:
9. Inom refers to the expected current based on the configuration of the device.
10. All outputs loaded as per maximum capacitive load table.
11. Absolute value = (programmed CPU Iref 97) +10 mA.
12. This parameter is measured as an average over 1Ps duration with a crystal center frequency of 14.318 MHz.
13. When XIN is driven from an external clock source.
14. All outputs loaded per Table 13 below.
15. Probes are placed on pins and measurements are acquired at 1.5V for 3.3V signals (see test and measurement set-up section).
16. This measurement is applicable with Spread ON or Spread OFF.
17. Measured at crossing point (Vx), or where subtraction of CLK–CLK# crosses 0V.
18. For CPU load. See Figure 8.
Rev 1.0, November 20, 2006
Page 17 of 21
CY28342
AC Parameters (continued)
100 MHz
Parameter
Tr/Tf
Description
CPU and CPUC Rise and Fall Times
Min.
175
Rise/Fall Matching
133 MHz
Max.
Min.
700
175
20%
Max.
Unit
700
ps
20%
Notes
16,19
18,19,20
DeltaTr
Rise Time Variation
125
125
ps
18,19
DeltaTf
Fall Time Variation
125
125
ps
18,19
Vcross
Crossing Point Voltage at 0.7V Swing
280
430
280
430
mV
17,18,19
AGP
TDC
AGP Duty Cycle
45
55
45
55
%
14, 15
TPeriod
AGP Period
15.0
15.3
15.0
15.3
ns
14, 15
THIGH
AGP HIGH Time
5.25
ns
21
TLOW
AGP LOW Time
5.05
Tr/Tf
AGP Rise and Fall Times
0.5
Tskew
Unbuffered
Any AGP to Any AGP Clock Skew
TCCJ
AGP Cycle-to-Cycle Jitter
ZCLK
TDC
ZCLK(0:1) Duty Cycle
45
Tr/Tf
ZCLK(0:1) Rise and Fall Times
0.5
TSKEW
Any ZCLK(0:1) to Any ZCLK(0:1) Skew
175
TCCJ
ZCLK(0:1) Cycle-to-Cycle Jitter
250
PCI
TDC
PCI_F(0:1) PCI (0:5) Duty Cycle
TPeriod
PCI_F(0:1) PCI (0:5) Period
30.0
THIGH
PCI_F(0:1) PCI (0:5) HIGH Time
12.0
TLOW
PCI_F(0:1) PCI (0:5) LOW Time
12.0
Tr/Tf
PCI_F(0:1) PCI (0:5) Rise and Fall times
0.5
45
5.25
5.05
ns
22
1.6
ns
14, 23
175
175
ps
14, 15
250
250
ps
14, 15
55
%
14, 15
1.6
ns
14, 23
175
ps
14, 15
250
ps
14,15
55
%
14, 15
30.0
nS
12,14,15
12.0
nS
21
1.6
0.5
55
45
1.6
0.5
55
45
12.0
2.0
0.5
2.0
nS
22
nS
14, 23
TSKEW
Any PCI Clock to Any PCI Clock Skew
500
500
ps
14, 15
TCCJ
PCI_F(0:1) PCI (0:5) Cycle-to-Cycle Jitter
250
250
ps
14, 15
SDCLK
TDC
SDCLK Duty Cycle
45
55
45
55
%
14, 15
TPeriod
SDCLK Period
9.8
10.2
7.35
7.65
ns
14, 15
THIGH
SDCLK HIGH Time
3.0
1.87
ns
21
TLOW
SDCLK LOW Time
2.8
1.67
ns
22
Tr/Tf
SDCLK Rise and Fall Times
0.4
1.6
0.4
1.6
ns
14, 23
TCCJ
SDCLK Cycle-to-Cycle Jitter
–
250
–
250
ps
14, 23
45
55
45
55
48M
TDC
48M Duty Cycle
TPeriod
48M Period
Tr/Tf
48M Rise and Fall Times
TCCJ
48M Cycle-to-Cycle Jitter
20.829 20.834 20.829 20.834
1.0
2.0
350
1.0
%
14, 15
ns
14, 15
2.0
ns
14, 23
350
ps
14, 15
Notes:
19. Measured from VOL = 0.175 to VOH = 0.525V.
20. Determined as a fraction of 2*(Trise–Tfall)/(Trise+Tfall).
21. THIGH is measured at 2.4V for all non-host outputs.
22. TLOW is measured at 0.4V for all non-host outputs.
23. Probes are placed on pins and measurements are acquired between 0.4V and 2.4V for 3.3V signals (see test and measurement set-up section).
Rev 1.0, November 20, 2006
Page 18 of 21
CY28342
AC Parameters (continued)
100 MHz
Parameter
Description
24M
TDC
24-MHz Duty Cycle
TPeriod
24-MHz Period
Tr/Tf
24-MHz Rise and Fall Times
TCCJ
24-MHz Cycle-to-Cycle Jitter
REF
TDC
REF Duty Cycle
TPeriod
REF Period
Tr/Tf
REF Rise and Fall Times
TCCJ
REF Cycle-to-Cycle Jitter
Min.
Max.
133 MHz
Min.
Max.
Unit
45
55
45
55
%
14, 15
41.66
41.67
41.66
41.67
ns
14, 15
4.0
1.0
4.0
ns
14, 23
500
ps
14, 15
1.0
500
45
55
45
55
%
14, 15
69.8413
71.0
69.8413
71.0
ns
14, 15
4.0
1.0
1.0
1000
4.0
ns
14, 23
1000
ps
14, 15
ENABLE/DISABLE and SET UP
tpZL, tpZH
Output Enable Delay (All Outputs)
1.0
10.0
1.0
10.0
ns
tpLZ, tpZH
1.0
10.0
1.0
10.0
ns
1.5
ms
Output Disable Delay (All Outputs)
tstable
All Clock Stabilization from Power-up
tss
Stopclock Set-up Time
tsh
Stopclock Hold Time
Notes
1.5
10.0
10.0
ns
0
0
ns
24
Table 13.Maximum Lumped Capacitive Output Loads
Clock
Max. Load
Units
PCI(0:5), PCI_F(0:1)
30
pF
AGP (0:1), SDCLK
30
pF
ZCLK (0:1)
30
pF
48M_24, 48M Clock
20
pF
REF (0:2)
30
pF
CPU(0:1)T
CPU(0:1) C
2
pF
Notes:
24. CPU_STP# and PCI_STP# set-up time with respect to any PCI_F clock to guarantee that the affected clock will stop or start at the next PCI_F clock’s rising edge.
25. When crystal meets minimum 40 ohm device series resistance specification.
26. This is required for the duty cycle on the REF clock out to be as specified. The device will operate reliably with input duty cycles up to 30/70, but the REF clock
duty cycle will not be within data sheet specifications.
Rev 1.0, November 20, 2006
Page 19 of 21
CY28342
Test and Measurement Set-up
For Differential CPU Output Signals
The following diagram shows lumped test load configurations
for the differential Host Clock Outputs.
T PCB
33:
Measurem ent Point
CPUT
49.9:
2 pF
MULTSEL
T PCB
33:
Measurem ent Point
CPUC
2 pF
49.9:
IREF
475:
Figure 8. 0.7V Configuration
O u tp u t u n d e r T e s t
P ro b e
Load Cap
3 .3 V s ig n a l s
tD C
-
-
3 .3 V
2 .4 V
1 .5 V
0 .4 V
0V
Tr
Tf
Figure 9. Lumped Load For Single-Ended Output Signals (for AC Parameters Measurement)
Ordering Information
Part Number
Package Type
Product Flow
CY28342OC
48-pin Shrunk Small Outline Package (SSOP)
Commercial 0q to 70qC
CY28342OCT
48-pin Shrunk Small Outline Package (SSOP) – Tape and Reel
Commercial 0q to 70qC
CY28342ZC
48-pin Thin Shrunk Small Outline Package (TSSOP)
Commercial 0q to 70qC
CY28342ZCT
48-pin Thin Shrunk Small Outline Package (TSSOP) – Tape and Reel Commercial 0q to 70qC
Rev 1.0, November 20, 2006
Page 20 of 21
CY28342
Package Drawing and Dimensions
48-lead Shrunk Small Outline Package O48
48-lead Thin Shrunk Small Outline Package, Type II (6 mm x 12 mm) Z48
51 85059 *B
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 20, 2006
Page 21 of 21