ICS ICS950811

ICS950811
Integrated
Circuit
Systems, Inc.
Frequency Generator with 200MHz Differential CPU Clocks
Recommended Application:
CK-408 clock for Brookdale-Mobile chipsets.
Programmable for group to group skew.
Pin Configuration
Output Features:
•
3 Differential CPU Clock Pairs (differential current
mode)
•
7 PCI (3.3V) @ 33.3MHz
•
3 PCI_F (3.3V) @ 33.3MHz
•
1 USB (3.3V) @ 48MHz
•
1 DOT (3.3V) @ 48MHz
•
1 REF (3.3V) @ 14.318MHz
•
5 3V66 (3.3V) @ 66.6MHz
•
1 VCH/3V66 (3.3V) @ 48MHz or 66.6MHz
Features:
•
Supports spread spectrum modulation,
down spread 0 to -0.5%.
•
Efficient power management scheme through PD#,
CPU_STOP# and PCI_STOP#.
56 pin SSOP/TSSOP
Key Specifications:
•
CPU Output Jitter <150ps
•
3V66 Output Jitter <250ps
•
66MHz Output Jitter (Buffered Mode Only) <100ps
•
CPU Output Skew <100ps
Block Diagram
* These inputs have 150K internal pull-up resistor to VDD.
Functionality
FS2 FS1 FS0
0482E—08/09/07
CPU
(MHz)
HzOut(2:0)
3V66(1:0) 66M
3V66(4:2)
(MHz)
(MHz)
PCI_F
PCI
(MHz)
66MHzIn
3V66(5)
(MHz)
0
0
0
66.66
66.66
66.66
33.33
66.66
0
0
1
100.00
66.66
66.66
33.33
66.66
0
1
0
200.00
66.66
66.66
33.33
66.66
0
1
1
133.33
66.66
66.66
33.33
66.66
1
0
0
66.66
66.66
1
0
1
100.00
66.66
1
1
0
200.00
66.66
Buffered Mode
Not Suppor ted
See ICS950805
1
1
1
133.33
66.66
Mid
0
0
Tristate
Tristate
Tristate
Tristate
Tristate
Mid
0
1
TCLK/2
TCLK/4
TCLK/4
TCLK/8
TCLK/4
Mid
1
0
Reser v- Reser ved
ed
Reser ved
Reser ved
Reser ved
Mid
1
1
Reser v- Reser ved
ed
Reser ved
Reser ved
Reser ved
ICS950811
Pin Configuration
PIN NUMBER
PIN NAME
TYPE
1, 8, 14, 19, 26,
32, 37, 46, 50
DESCRIPTION
VDD
PWR
2
X1
X2 Cr ystal
Input
14.318MHz Cr ystal input
3
X2
X1 Cr ystal
Output
14.318MHz Cr ystal output
7, 6, 5
PCICLK_F (2:0)
OUT
Free running PCI clock not affected by PCI_STOP# for
power management.
4, 9, 15, 20, 27,
31, 36, 41, 47
GND
PWR
Ground pins for 3.3V supply
18, 17, 16, 13,
12,11, 10
PCICLK (6:0)
OUT
PCI clock outputs
24, 23, 22, 21
3V66 (5:2)
OUT
66MHz reference clocks, from internal VCO
3.3V power supply
25
PD#
IN
28
Vtt_PWRGD#
IN
Invokes power-down mode. Active Low.
29
SDATA
I/O
Data pin for I2C circuitry 5V tolerant
30
SCLK
IN
Clock pin of I2C circuitry 5V tolerant
33
3V66_0
OUT
66MHz reference clocks, from internal VCO
Halts PCICLK clocks at logic 0 level, when input low except
PCICLK_F which are free running
34
PCI_STOP#
IN
35
3V66_1/VCH_CLK
OUT
3.3V output selectable through I2C to be 66MHz from internal
VCO or 48MHz (non-SSC)
38
48MHz_DOT
OUT
48MHz output clock for DOT
48MHz output clock for USB
39
48MHz_USB
OUT
40
FS2
IN
42
I REF
OUT
43
MULTSEL0
IN
44, 48, 51
CPUCLKC (2:0)
OUT
"Complementor y" clocks of differential pair CPU outputs. These
are current outputs and external resistors are required for
voltage bias.
45, 49, 52
CPUCLKT (2:0)
OUT
"True" clocks of differential pair CPU outputs. These are current
outputs and external resistors are required for voltage bias.
Special 3.3V input for Mode selection
This pin establishes the reference current for the CPUCLK
pairs. This pin requires a fixed precision resistor tied to ground
in order to establish the appropriate current.
3.3V LVTTL input for selecting the current multiplier for CPU
outputs
53
CPU_STOP#
IN
Halts CPUCLK clocks at logic 0 level, when input low
55, 54
FS (1:0)
IN
Frequency select pins
56
REF
OUT
14.318MHz reference clock.
Power Groups
(Analog)
VDDA = PLL1
VDD48 = 48MHz, PLL
VDDREF = VDD for Xtal, POR
(Digital)
VDDPCI
VDD3V66
VDDCPU
0482E—08/09/07
2
ICS950811
Truth Table
FS2
FS1
FS0
CPU
(MHz)
3V66
(1:0)
(MHz)
66Buff (2:0)
3V66 (4:2)
(MHz)
66MHz_IN/
3V66_5
PCI_F
PCI
(MHz)
REF0
(MHz)
USB/DOT
(MHz)
0
0
0
66.66
66.66
66.66
66.66
33.33
14.318
48.00
0
0
1
100.00
66.66
66.66
66.66
33.33
14.318
48.00
0
1
0
200.00
66.66
66.66
66.66
33.33
14.318
48.00
66.66
66.66
33.33
14.318
48.00
0
1
1
133.33
66.66
1
0
0
66.66
66.66
1
0
1
100.00
66.66
1
1
0
200.00
66.66
1
1
1
133.33
66.66
Mid
0
0
Tristate
Tristate
TCLK/2
TCLK/4
Buffered Mode Not Suppor ted
See ICS950805
Tristate
Tristate
Tristate
Tristate
Tristate
Mid
0
1
TCLK/4
TCLK/4
TCLK/8
TCLK
TCLK/2
Mid
1
0
Reser ved Reser ved
Reser ved
Reser ved
Reser ved
Reser ved
Reser ved
Mid
1
1
Reser ved Reser ved
Reser ved
Reser ved
Reser ved
Reser ved
Reser ved
Maximum Allowed Current
Condition
Max 3.3V supply consumption
Max discrete cap loads,
Vdd = 3.465V
All static inputs = Vdd or GND
Powerdown Mode
(PWRDWN# = 0)
40mA
Full Active
360mA
Host Swing Select Functions
MULTISEL0
Board Target
Trace/Term Z
Output
Current
Voh @ Z
Buffered Mode Not Suppor ted
See ICS950805
0
1
Reference R,
Iref =
VDD/(3*Rr)
50 ohms
Rr = 475 1%,
Iref = 2.32mA
0482E—08/09/07
3
Ioh = 6* I REF
0.7V @ 50
ICS950811
General I2C serial interface information
The information in this section assumes familiarity with I2C programming.
How to Write:
How to Read:
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
Controller (host) sends a start bit.
Controller (host) sends the write address D2 (H)
ICS clock will acknowledge
Controller (host) sends a dummy command code
ICS clock will acknowledge
Controller (host) sends a dummy byte count
ICS clock will acknowledge
Controller (host) starts sending first byte (Byte 0)
through byte 5
• ICS clock will acknowledge each byte one at a time.
Controller (host) will send start bit.
Controller (host) sends the read address D3 (H)
ICS clock will acknowledge
ICS clock will send the byte count
Controller (host) acknowledges
ICS clock sends first byte (Byte 0) through byte 6
Controller (host) will need to acknowledge each byte
Controller (host) will send a stop bit
How to Write:
Controller (Host)
Start Bit
Address
D2(H)
ICS (Slave/Receiver)
How to Read:
Controller (Host)
Start Bit
Address
D3(H)
ACK
Dummy Command Code
ACK
ICS (Slave/Receiver)
ACK
Byte Count
Dummy Byte Count
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
ACK
Stop Bit
Byte 0
Byte 0
Byte 1
Byte 1
Byte 2
Byte 2
Byte 3
Byte 3
Byte 4
Byte 4
Byte 5
Byte 5
Byte 6
Byte 6
Stop Bit
Notes:
1.
2.
3.
4.
5.
6.
The ICS clock generator is a slave/receiver, I2C component. It can read back the data stored in the latches
for verification. Read-Back will support Intel PIIX4 "Block-Read" protocol.
The data transfer rate supported by this clock generator is 100K bits/sec or less (standard mode)
The input is operating at 3.3V logic levels.
The data byte format is 8 bit bytes.
To simplify the clock generator I2C interface, the protocol is set to use 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. The Command code and Byte count shown above must be
sent, but the data is ignored for those two bytes. The data is loaded until a Stop sequence is issued.
At power-on, all registers are set to a default condition, as shown.
0482E—08/09/07
4
ICS950811
Byte 0: Control Register
Bit
Pin#
Name
PWD2
Type1
Bit 0
54
FS0
X
R
Bit 1
55
FS1
X
R
Bit 2
40
FS2
X
R
X
R
Bit 3
34
PCI_STOP#3
1
RW
Bit 4
53
CPU_STOP#
X
R
Bit 5
35
3V66_1/VCH
0
RW
Bit 6
-
CPU_T(2:0)
0
Bit 7
-
Spread
Enabled
0
RW
Description
Reflects the value of FS0 pin sampled on
power up
Reflects the value of FS1 pin sampled on
power up
Reflects the value of FS2 pin sampled on
power up
Hardware mode: Reflects the value of
PCI_STOP# pin sampled on PWD
Software mode:
0=PCICLK stopped
1=PCICLK not stopped
Reflects the current value of the external
CPU_STOP# pin
VCH Select 66MHz/48MHz
0=66MHz, 1=48MHz
In power down mode controls output level
0=stop high
1=stop low
0=Spread Off, 1=Spread On
Byte 1: Control Register
PWD2
Type1
1
RW
0=Disabled 1=Enabled4
1
RW
0=Disabled 1=Enabled4
45, 44
Name
CPUCLKT0
CPUCLKC0
CPUCLKT1
CPUCLKC1
CPUCLKT2
CPUCLKC2
1
RW
0=Disabled 1=Enabled4
Bit 3
52, 51
CPUCLKT0
CPUCLKC0
0
RW
Bit 4
49, 48
CPUCLKT1
CPUCLKC1
0
RW
Bit 5
45, 44
CPUCLKT2
CPUCLKC2
0
RW
B it 6
Bit 7
43
MULTSEL0
0
X
R
Bit
Pin#
Bit 0
52, 51
Bit 1
49, 48
Bit 2
Description
Allow control of CPUCLKT0/C0 with asser tion
of CPU_STOP# 0=Not free running 1=Free
running
Allow control of CPUCLKT1/C1 with asser tion
of CPU_STOP# 0=Not free running 1=Free
running
Allow control of CPUCLKT2/C2 with asser tion
of CPU_STOP# 0=Not free running 1=Free
running
(Reserved)
Reflects the current value of MULTSEL0
Notes:
1. R= Read only RW= Read and Write
2. PWD = Power on Default
3. The purpose of this bit is to allow a system designer to implement PCI_STOP functionality in one of two ways.
Wither the system designer can choose to use the externally provided PCI_STOP# pin to assert and de-assert
PCI_STOP functionality via I2C Byte 0 Bit 3.
In Hardware mode it is not allowed to write to the I2C Byte 0 Bit3. In Software mode it is not allowed to pull the
external PCI_STOP pin low. This avoids the issues related with Hardware started and software stopped
PCI_STOP conditions. The clock chip is to be operated in the Hardware or Software PCI_STOP mode ONLY, it
is not allowed to mix these modes.
In Hardware mode the I2C byte 0 Bit 3 is R/W and should reflect the status of the part. Whether or not the chip
is in PCI_STOP mode.
Functionality PCI_STOP mode should be entered when [(PCI_STOP#=0) or (I2C Byte 0 Bit 3 = 0)].
4. For disabled clocks, they stop low for single ended clocks. Differential CPU clocks stop with CPUCLKT at high,
CPUCLKC off, and external resistor termination will bring CPUCLKC low.
0482E—08/09/07
5
ICS950811
Byte 2: Control Register
Bit
Bit 0
Bit 1
Bit 2
B it 3
B it 4
Bit 5
B it 6
Bit 7
Pin#
10
11
12
13
16
17
18
-
Name
PCICLK0
PCICLK1
PCICLK2
PCICLK3
PCICLK4
PCICLK5
PCICLK6
-
PWD
1
1
1
1
1
1
1
0
Type
RW
RW
RW
RW
RW
RW
RW
-
Description
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
(Reserved)
Description
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
Allow control of PCICLK_F0 with asser tion of
PCI_STOP#. 0=Free Running, 1=Not free
running
Allow control of PCICLK_F1 with asser tion of
PCI_STOP#. 0=Free Running, 1=Not free
running
Allow control of PCICLK_F2 with asser tion of
PCI_STOP#. 0=Free Running, 1=Not free
running
0=Disabled 1=Enabled
0=Disabled 1=Enabled
Byte 3: Control Register
Bit
Bit 0
Bit 1
Bit 2
Pin#
5
6
7
Name
PCICLK_F0
PCICLK_F1
PCICLK_F2
PWD
1
1
1
Type
RW
RW
RW
Bit 3
5
PCICLK_F0
0
RW
Bit 4
6
PCICLK_F1
0
RW
Bit 5
7
PCICLK_F2
0
RW
Bit 6
Bit 7
39
38
48MHz_USB
48MHz_DOT
1
1
RW
RW
Byte 4: Control Register
Bit
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Pin#
21
22
23
24
35
33
-
Name
3V66-2
3V66-3
3V66-4
3V66_5
3V66_1/VCH_CLK
3V66_0
-
PWD
1
1
1
1
1
1
0
0
Type
RW
RW
RW
RW
RW
RW
R
R
Notes:
1. R= Read only RW= Read and Write
2. PWD = Power on Default
0482E—08/09/07
6
Description
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
0=Disabled 1=Enabled
(Reserved)
(Reserved)
ICS950811
Byte 5: Programming Edge Rate
(1 = enable, 0 = disable)
Bit
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Pin#
X
X
X
X
X
X
X
X
Name
48MHz_USB
48MHz_USB
48MHz_DOT
48MHz_DOT
-
PWD
0
0
0
0
0
0
0
0
Type
RW
RW
RW
RW
-
PWD
1
1
1
1
1
1
1
1
Type
R
R
R
R
R
R
R
R
Description
USB edge rate cntrol
USB edge rate cntrol
DOT edge rate control
DOT edge rate control
(Reserved)
(Reserved)
(Reserved)
(Reserved)
Byte 6: Vendor ID Register
(1 = enable, 0 = disable)
Bit
Bit 0
Bit 1
Bit 2
Bit 3
Bit 4
Bit 5
Bit 6
Bit 7
Pin#
X
X
X
X
X
X
X
X
Name
Vendor ID Bit0
Vendor ID Bit1
Vendor ID Bit2
Vendor ID Bit3
Revision ID Bit0
Revision ID Bit1
Revision ID Bit2
Revision ID Bit3
Notes:
1. R= Read only RW= Read and Write
2. PWD = Power on Default
0482E—08/09/07
7
Description
(Reserved)
(Reserved)
(Reserved)
(Reserved)
Revision ID values will be based on
individual device's revision
ICS950811
Absolute Maximum Ratings
Supply Voltage . . . . . . . . . . . . . . . . . . . . . . . . . 5.5 V
Logic Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . GND –0.5 V to VDD + 0.5 V
Ambient Operating Temperature . . . . . . . . . . 0°C to +85°C
Case Temperature . . . . . . . . . . . . . . . . . . . . . . 115°C
Storage Temperature . . . . . . . . . . . . . . . . . . . . –65°C to +150°C
Stresses above those listed under Absolute Maximum Ratings may cause permanent damage to the device. These
ratings are stress specifications only and functional operation of the device at these or any other conditions above those
listed in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions
for extended periods may affect product reliability.
Electrical Characteristics - Input/Supply/Common Output Parameters
TA = 0 - 70°C; Supply Voltage VDD = 3.3 V +/-5%
PARAMETER
Input High Voltage
Input Low Voltage
Input High Current
SYMBOL
CONDITIONS
VIH
VIL
IIH
V IN = VDD
IIL1
V IN = 0 V; Inputs with no pull-up resistors
MIN
2
V SS - 0.3
-5
-5
TYP
MAX
VDD + 0.3
0.8
5
Input Low Current
mA
IIL2
Operating Supply
Current
IDD3.3OP
IDD3.3OP
Powerdown Current
Input Frequency
Pin Inductance
1
Input Capacitance
1
Transition time
Settling time1
Clk Stabilization1
Time to first clock1
Delay1
UNITS
V
V
mA
mA
I DD3.3PD
Fi
Lpin
CIN
COUT
CINX
Ttrans
Ts
TSTAB
T1C
tPZH,tPZL
tPHZ,tPLZ
V IN = 0 V; Inputs with pull-up resistors
-200
CL = Full load; Select @ 100 MHz
229
230
360
CL =Full load; Select @ 133 MHz
IREF=5 mA
V DD = 3.3 V
220
233
360
38.1
14.318
45
Logic Inputs
Output pin capacitance
X1 & X2 pins
To 1st crossing of target frequency
From 1st crossing to 1% target frequency
From VDD = 3.3 V to 1% target frequency
Time to first clock
Output enable delay (all outputs)
Output disable delay (all outputs)
1
Guaranteed by design, not 100% tested in production.
0482E—08/09/07
8
27
36
1
1
1
mA
mA
7
5
6
45
3
3
3
mA
MHz
nH
pF
pF
pF
ms
ms
ms
1.8
10
10
ms
ns
ns
ICS950811
Electrical Characteristics - CPU
TA = 0 - 70°C; VDD=3.3V +/-5%; CL = 10-20 pF (unless otherwise specified)
PARAMETER
Current Source
Output Impedance
SYMBOL
Output High Voltage
Output Low Voltage
Rise Time
Fall Time
VOH3
VOL3
tr3
tf3
Duty Cycle
dt3
Skew
tsk3
Jitter, Cycle to cycle
Zo1
tjcyc-cyc
CONDITIONS
VO = Vx
IOH = -1 mA
IOL = 1 mA
VOL = 0.41V, VOH = 0.86V
VOH = 0.86V VOL = 0.41V
1
measurement from differential wavefrom 0.35V to +035V
VT = 50%
VT = 50%
MIN
TYP
MAX UNITS
Ω
V
3000
2.4
175
175
240
242
0.4
700
700
45
51
55
%
50
100
ps
76
150
ps
ps
ps
1
Guaranteed by design, not 100% tested in production.
IOWT can be varied and is selectable thru the MULTSEL pin.
2
Electrical Characteristics - PCICLK
TA = 0 - 70C; VDD=3.3V +/-5%; CL = 10-30 pF (unless otherwise specified)
PARAMETER
Output Frequency
SYMBOL
FO1
Output Impedance
RDSP11
Output High Voltage
VOH1
VOL1
IOH1
IOL1
tr11
tf11
dt11
tsk11
Output Low Voltage
Output High Current
Output Low Current
Rise Time
Fall Time
Duty Cycle
Skew
Jitter,cycle to cyc
tjcyc-cyc
1
CONDITIONS
MIN
TYP
33.33
MAX
UNITS
MHz
VO = VDD*(0.5)
12
33
55
Ω
IOH = -1 mA
2.4
IOL = 1 mA
V OH@MIN = 1.0 V, V OH@MAX = 3.135 V
VOL @MIN = 1.95 V, VOL @MAX = 0.4 V
-33
30
VOL = 0.4 V, VOH = 2.4 V
0.5
VOH = 2.4 V, VOL = 0.4 V
VT = 1.5 V
VT = 1.5 V
VT = 1.5 V
1
Guaranteed by design, not 100% tested in production.
0482E—08/09/07
9
V
0.55
-33
38
V
mA
mA
1.32
0.5to 2
ns
0.5
1.39
0.5 to 2
ns
45
52
55
%
247
500
ps
111
500
ps
ICS950811
Electrical Characteristics - 3V66
TA = 0 - 70°C; VDD=3.3V +/-5%; CL = 10-30 pF (unless otherwise specified)
PARAMETER
SYMBOL
Output Frequency
FO1
RDSP11 VO = VDD*(0.5)
Output Impedance
Duty Cycle
VOH1
VOL1
IOH1
IOL1
tr11
tf11
dt11
Skew
tsk11
Output High Voltage
Output Low Voltage
Output High Current
Output Low Current
Rise Time
Fall Time
Jitter
CONDITIONS
tjcyc-cyc
IOH = -1 mA
1
MIN
TYP
66.66
MAX
UNITS
MHz
12
33
55
Ω
2.4
IOL = 1 mA
V OH@MIN = 1.0 V, V OH@MAX = 3.135
VOL @MIN = 1.95 V, VOL @MAX = 0.4 V
-33
30
VOL = 0.4 V, VOH = 2.4 V
0.5
VOH = 2.4 V, V OL = 0.4 V
VT = 1.5 V
V
0.55
-33
38
V
mA
mA
1.38
2
ns
0.5
1.45
2
ns
45
54.4
55
%
243
500
ps
139
300
ps
VT = 1.5 V
VT = 1.5 V 3V66
1
Guaranteed by design, not 100% tested in production.
Electrical Characteristics - VCH, 48MHz DOT, 48MHz, USB
TA = 0 - 70°C; VDD=3.3V +/-5%; CL = 10-20 pF (unless otherwise specified)
PARAMETER
Output Frequency
Output Impedance
SYMBOL
FO1
CONDITIONS
RDSP11 V O = V DD*(0.5)
MIN
TYP
48
20
48
Output High Voltage
VOH1
IOH = -1 mA
Output Low Voltage
Output High Current
Output Low Current
48DOT Rise Time
VOL1
IOL = 1 mA
V OH@MIN = 1.0 V, V OH@MAX = 3.135 V
V OL @MIN = 1.95 V, VOL @MAX = 0.4 V
-29
29
V OL = 0.4 V, V OH = 2.4 V
0.5
V OH = 2.4 V, VOL = 0.4 V
48DOT Fall Time
VCH 48 USB Rise Time
VCH 48 USB Fall Time
48 DOT Duty Cycle
VCH 48 USB Duty Cycle
48 DOT Jitter
VCH Jitter
IOH1
IOL1
tr11
tf11
tr11
tf11
dt11
dt11
MAX UNITS
MHz
60
2.4
Ω
V
0.4
-23
27
V
mA
mA
0.6
1
ns
0.5
0.8
1
ns
V OL = 0.4 V, V OH = 2.4 V
1
1.2
2
ns
V OH = 2.4 V, VOL = 0.4 V
1
1.3
2
ns
V T = 1.5 V
45
52.8
55
%
V T = 1.5 V
45
53.5
55
%
183
350
ps
223
350
ps
1
tjcyc-cyc V T = 1.5 V
tjcyc-cyc 1 V T = 1.5 V
1
Guaranteed by design, not 100% tested in production.
0482E—08/09/07
10
ICS950811
Electrical Characteristics - REF
TA = 0 - 70°C; VDD=3.3V +/-5%; CL = 10-20 pF (unless otherwise specified)
PARAMETER
Output Frequency
SYMBOL
FO1
Output Impedance
RDSP11
Output High Voltage
VOH1
VOL1
IOH1
IOL1
tr11
tf11
dt11
Output Low Voltage
Output High Current
Output Low Current
Rise Time
Fall Time
Duty Cycle
Jitter
tjcyc-cyc
CONDITIONS
VO = VDD*(0.5)
20
IOH = -1 mA
2.4
IOL = 1 mA
V OH@MIN = 1.0 V, V OH@MAX = 3.135 V
VOL @MIN = 1.95 V, VOL @MAX = 0.4 V
1
MIN
TYP
MAX UNITS
14.318
MHz
48
60
Ω
V
-29
29
0.4
-23
27
V
mA
mA
VOL = 0.4 V, VOH = 2.4 V
1
1.25
2
ns
VOH = 2.4 V, V OL = 0.4 V
1
1.15
2
ns
45
53
55
%
723
1000
ps
VT = 1.5 V
VT = 1.5 V
1
Guaranteed by design, not 100% tested in production.
0482E—08/09/07
11
ICS950811
Un-Buffered Mode 3V66 & PCI Phase Relationship
All 3V66 clocks are to be in pphase with each other. In the case where 3V66_1 is configured as 48MHz VCH clock,
there is no defined phase relationship between 3V66_1/VCH and other 3V66 clocks. The PCI group should lag 3V66
by the standard skew described below as Tpci.
3V66 (1:0)
3V66 (4:2)
3V66_5
Tpci
PCICLK_F (2:0) PCICLK (6:0)
Group Skews at Common Transition Edges: (Un-Buffered Mode)
GROUP
3V66
PCI
3V66 to PCI
SYMBOL
CONDITIONS
3V66
3V66 (5:0) pin to pin skew
PCI
S3V66-PCI
PCI_F (2:0) and PCI (6:0) pin to pin skew
3V66 (5:0) leads 33MHz PCI
1
Guaranteed by design, not 100% tested in production.
0482E—08/09/07
12
MIN
0
TYP
42
MAX UNITS
500
ps
0
130
500
ps
1.5
2.86
3.5
ns
ICS950811
Normal operation transition to Suspend State S1 Entry sequence of events:
1. Power-Down (PD#) pin is taken from a high to low to start into S1 Suspend state with digital filtering of the
transition in the clock circuit.
2. The first clocks to be forced to a Stop Low power down condition are the PCI buffer output clocks after a full
clock cycle. If the PCI_Stop# is low, then the free-running PCI clocks (for PCI and APIC signals) are the
remaining PCI buffer clocks stopped.
3. Immediately after the PCI clocks have been stopped the 66Buf_0:2 clocks are stopped low after the next
high to low transition. It will always be a sequence of PCI stopping, THEN the 66Buf clocks.
4. Following the two buffer output clocks being stopped (PCI then 66.6Buffer outputs), the remaining clocks
within a short delay will transition to a stopped power-down state. The first of these driven clocks that
transition to a stopped state are all of the CPU PLL clocks: the CPU and the driven 3V66 clocks.
5. After the CPU PLL clocks are stopped, the 48 MHz clocks (USB, DOT clocks) will stop low, then the REF
clock 14.318 MHz clock will stop low.
6. After the clocks have all been stopped, the internal PLL stages and the Crystal oscillator will all be driven to
a low power stopped condition.
7. As a note to power management calculations, please be aware that the CPU design requires that in the
Power-Down (S1 mode) the CPU outputs have a differential bias voltage driving the differential input stage of
the CPU in this S1 state. For this PD condition of the clock generator, the IDD_PD is running around 30 to
45 mA from having the Iref running (5 mA), the output multiplier bias generator at a 2X condition and the
output current source outputs are running at a 2xIref bias level (for approx 10 mA each CPU output). This
results in a higher level of Clock generator IDD_PD than in prior generations of clocks due to the CPU output
differential requirements.
Suspend State S1 Exit transition to normal operation sequence of events:
1. Power-Down (PD#) pin is taken from Low to High with digital filtering of the transition in the clock circuit to
return to normal running operation.
2. The Crystal Oscillator and the two PLL stages are released from PD to start-up to normal operation. No
clocks will operate until the Lock detect circuitry verifies the PLL has reached stable final frequency (the
same as normal initial power-up).
3. The CPU PLL clocks (differential CPU outputs and the driven 3V66_(0:1) clocks are operating first as soon
as the Lock detect releases the clocks. With the release of these clocks, the single 66Buf_1 buffer driven
output (at pin 22) is also released from the PD stopped state (but NOT the other 66Buf0,2 and not the PCI
outputs). This allows the GMCH chipset 66.6 MHz DLL stage to start operating and have an operating
feedback path before the other buffer outputs are released. This change is why the requirement is made that
pin 22 be the connection from the clock to the GMCH chipset. Note that along with the 66Buf_0,2 and the
PCI clocks, the 48 MHz and REF (14.318 MHz) clocks are also NOT released at this point.
4. A delay is built into the clock generator that allows the CPU, driven 3V66_0,1 and the single buffer clock
66Buf_1 (at pin 22) to operate before other clocks are released. This delay is larger than 30 uS and shorter
than 400 uS, and after this the other clocks are staged for a sequential release.
5. The initial clocks released after the delay are the 66Buf_0, 2 outputs.
6. After the 66Buf_0,2 clocks are released, then the PCI clocks are released.
7. It will always be the sequence of 66_1 (pin 22) released with the CPU clocks, then after the delay the
remaining 66Buf_0,2 first, THEN the PCI clocks.
8. Following the 66Buf_0,2 clocks, the 48 MHz (DOT and USB clocks) and the REF (14.318MHz) clocks are
released.
9. Note, the initial power-up time is the same as this PD release, the PLL will power-up and the outputs will be
running within a 3 ms time point.
0482E—08/09/07
13
ICS950811
PCI_STOP# - Assertion (transition from logic "1" to logic "0")
The impact of asserting the PCI_STOP# signal will be the following. All PCI[6:0] and stoppable PCI_F[2,0] clocks will
latch low in their next high to low transition. The PCI_STOP# setup time tsu is 10 ns, for transitions to be recognized
by the next rising edge.
Assertion of PCI_STOP# Waveforms
PCI_STOP#
PCI_F[2:0] 33MHz
PCI[6:0] 33MHz
tsu
CPU_STOP# - Assertion (transition from logic "1" to logic "0")
The impact of asserting the CPU_STOP# pin is all CPU outputs that are set in the I2C configuration to be stoppable
via assertion of CPU_STOP# are to be stopped after their next transition following the two CPU clock edge sampling
as shown. The final state of the stopped CPU signals is CPUT=High and CPUC=Low. There is to be no change to the
output drive current values. The CPUT will be driven high with a current value equal to (MULTSEL0) X (I REF), the CPUC
signal will not be driven.
Assertion of CPU_STOP# Waveforms
CPU_STOP#
CPUT
CPUC
CPU_STOP# Functionality
CPU_STOP#
CPUT
CPUC
1
Normal
Normal
0
iref * Mult
Float
0482E—08/09/07
14
ICS950811
PD# - Assertion (transition from logic "1" to logic "0")
When PD# is sampled low by two consecutive rising edges of CPU clock then all clock outputs except CPU clocks
must be held low on their next high to low transition. CPU clocks must be held with the CPU clock pin driven high with
a value of 2x Iref, and CPUC undriven. Note the example below shows CPU = 100MHz, this diagram and description
is applicable for all valid CPU frequencies 66, 100, 133, 200MHz.
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.
Power Down Assertion of Waveforms - Buffered Mode
25ns
0ns
50ns
PD#
CPUT 100MHz
CPUC 100MHz
3V66MHz
66MHz_IN
66MHz_OUT
PCI 33MHz
USB 48MHz
REF 14.318MHz
PD# Functionality
CPU_STOP#
CPUT
CPUC
3V66
66MHz_OUT
PCICLK_F
PCICLK
PCICLK
USB/DOT
48MHz
1
Normal
Normal
66MHz
66MHz_IN
66MHz_IN
66MHz_IN
48MHz
0
iref * Mult
Float
Low
Low
Low
Low
Low
0482E—08/09/07
15
ICS950811
c
N
L
E1
INDEX
AREA
E
1 2
a
D
A
A2
In Millimeters
In Inches
SYMBOL COMMON DIMENSIONS COMMON DIMENSIONS
MIN
MAX
MIN
MAX
A
-1.20
-.047
A1
0.05
0.15
.002
.006
A2
0.80
1.05
.032
.041
b
0.17
0.27
.007
.011
c
0.09
0.20
.0035
.008
D
SEE VARIATIONS
SEE VARIATIONS
E
8.10 BASIC
0.319 BASIC
E1
6.00
6.20
.236
.244
e
0.50 BASIC
0.020 BASIC
L
0.45
0.75
.018
.030
N
SEE VARIATIONS
SEE VARIATIONS
0°
8°
0°
8°
α
aaa
-0.10
-.004
A1
-Ce
b
N
SEATING
PLANE
56
aaa C
VARIATIONS
D mm.
MIN
MAX
13.90
14.10
Ref erence Doc.: JEDEC Publicat ion 95, M O-153
6.10 mm. Body, 0.50 mm. pitch TSSOP
(0.020 mil)
(240 mil)
10-0039
Ordering Information
ICS950811yGLFT
Example:
ICS XXXX y G - LF - T
Designation for tape and reel packaging
Lead Free, RoHS Compliant (Optional)
Package Type
G = TSSOP
Revision Designator (will not correlate with datasheet revision)
Device Type
Prefix
ICS = Standard Device
0482E—08/09/07
16
D (inch)
MIN
.547
MAX
.555
ICS950811
56-Lead, 300 mil Body, 25 mil, SSOP
SYMBOL
A
A1
b
c
D
E
E1
e
h
L
N
α
In Millimeters
COMMON DIMENSIONS
MIN
MAX
2.41
2.80
0.20
0.40
0.20
0.34
0.13
0.25
SEE VARIATIONS
10.03
10.68
7.40
7.60
0.635 BASIC
0.38
0.64
0.50
1.02
SEE VARIATIONS
0°
8°
In Inches
COMMON DIMENSIONS
MIN
MAX
.095
.110
.008
.016
.008
.0135
.005
.010
SEE VARIATIONS
.395
.420
.291
.299
0.025 BASIC
.015
.025
.020
.040
SEE VARIATIONS
0°
8°
VARIATIONS
N
56
D mm.
MIN
18.31
D (inch)
MAX
18.55
Reference Doc.: JEDEC Publication 95, MO-118
10-0034
Ordering Information
ICS950811yFLFT
Example:
ICS XXXX y F - LF - T
Designation for tape and reel packaging
Lead Free, RoHS Compliant (Optional)
Package Type
F = SSOP
Revision Designator (will not correlate with datasheet revision)
Device Type
Prefix
ICS = Standard Device
0482E—08/09/07
17
MIN
.720
MAX
.730
ICS950811
Revision History
Rev.
D
E
Issue Date Description
1. Removed SSOP Package Information.
12/21/06 2. Added LF Ordering Information.
08/09/07 Added SSOP Package Information.
0482E—08/09/07
18
Page #
16
17