IDT ICS854S054I One differential lvds output pair Datasheet

4:1 Differential-to-LVDS Clock Multiplexer
ICS854S054I
DATA SHEET
General Description
Features
The ICS854S054I is a 4:1 Differential-to-LVDS Clock Multiplexer
which can operate up to 2.5GHz. The ICS854S054I has 4 selectable
differential clock inputs. The PCLK, nPCLK input pairs can accept
LVPECL, LVDS or CML levels. The fully differential architecture and
low propagation delay make it ideal for use in clock distribution
circuits. The select pins have internal pulldown resistors. The SEL1
pin is the most significant bit and the binary number applied to the
select pins will select the same numbered data input (i.e., 00 selects
PCLK0, nPCLK0).
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High speed 4:1 differential multiplexer
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Maximum output frequency: 2.5GHz
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Additive phase jitter, RMS: 0.147ps (typical)
One differential LVDS output pair
Four selectable differential PCLK, nPCLK input pairs
PCLKx, nPCLKx pairs can accept the following differential
input levels: LVPECL, LVDS, CML
Translates any single ended input signal to LVDS levels with
resistor bias on nPCLKx input
Part-to-part skew: 300ps (maximum)
Propagation delay: 700ps (maximum)
Supply voltage range: 3.135V to 3.465V
-40°C to 85°C ambient operating temperature
Available in lead-free (RoHS 6) package
Block Diagram
PCLK0
nPCLK0
PCLK1
nPCLK1
Pin Assignment
PCLK0
nPCLK0
PCLK1
nPCLK1
VDD
SEL0
SEL1
GND
Pulldown
Pullup/Pulldown
00 (default)
PCLK2
PCLK3
nPCLK3
16
15
14
13
12
11
10
9
VDD
Q
nQ
GND
nPCLK3
PCLK3
nPCLK2
PCLK2
Pulldown
Pullup/Pulldown
ICS854S054I
01
Q
nPCLK2
1
2
3
4
5
6
7
8
Pulldown
Pullup/Pulldown
nQ
10
16-Lead TSSOP
5.0mm x 4.4mm x 0.92mm package body
G Package
Top View
Pulldown
Pullup/Pulldown
SEL1
SEL0
11
Pulldown
Pulldown
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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©2012 Integrated Device Technology, Inc.
ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Table 1. Pin Descriptions
Number
Name
1
PCLK0
Input
Type
Pulldown
Non-inverting differential clock input.
Description
2
nPCLK0
Input
Pullup/
Pulldown
Inverting differential clock input. VDD/2 default when left floating.
3
PCLK1
Input
Pulldown
Non-inverting differential clock input.
4
nPCLK1
Input
Pullup/
Pulldown
Inverting differential clock input. VDD/2 default when left floating.
5, 16
VDD
Power
6, 7
SEL0, SEL1
Input
Pulldown
Clock select input pins. LVCMOS/LVTTL interface levels.
9
PCLK2
Input
Pulldown
Non-inverting differential clock input.
Inverting differential clock input. VDD/2 default when left floating.
Positive supply pins.
10
nPCLK2
Input
Pullup/
Pulldown
11
PCLK3
Input
Pulldown
Non-inverting differential clock input.
Pullup/
Pulldown
Inverting differential clock input. VDD/2 default when left floating.
12
nPCLK3
Input
8, 13
GND
Power
Power supply ground.
14, 15
nQ, Q
Output
Differential output pair. LVDS interface levels.
NOTE: Pullup and Pulldown refer to internal input resistors. See Table 2, Pin Characteristics, for typical values.
Table 2. Pin Characteristics
Symbol
Parameter
Test Conditions
Minimum
Typical
Maximum
Units
CIN
Input Capacitance
2
pF
RPULLDOWN
Pulldown Resistor
75
kΩ
RVDD/2
RPullup/Pulldown Resistor
50
kΩ
Table 3. Clock Input Function Table
Inputs
Outputs
SEL1
SEL0
Q
nQ
0
0
PCLK0
nPCLK0
0
1
PCLK1
nPCLK1
1
0
PCLK2
nPCLK2
1
1
PCLK3
nPCLK3
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Absolute Maximum Ratings
NOTE: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device.
These ratings are stress specifications only. Functional operation of product at these conditions or any conditions beyond
those listed in the DC Characteristics or AC Characteristics is not implied. Exposure to absolute maximum rating conditions for
extended periods may affect product reliability.
Item
Rating
Supply Voltage, VDD
4.6V
Inputs, VI
-0.5V to VDD + 0.5V
Outputs, IO
Continuous Current
Surge Current
10mA
15mA
Package Thermal Impedance, θJA
100°C/W (0 mps)
Storage Temperature, TSTG
-65°C to 150°C
DC Electrical Characteristics
Table 4A. Power Supply DC Characteristics, VDD = 3.3V ± 5%, TA = -40°C to 85°C
Symbol
Parameter
Test Conditions
VDD
Positive Supply Voltage
IDD
Power Supply Current
Minimum
Typical
Maximum
Units
3.135
3.3
3.465
V
57
68
mA
Typical
Maximum
Units
Table 4B. LVCMOS/LVTTL DC Characteristics, VDD = 3.3V ± 5%, TA = -40°C to 85°C
Symbol
Parameter
Test Conditions
Minimum
VIH
Input High Voltage
2.2
VDD + 0.3
V
VIL
Input Low Voltage
-0.3
0.8
V
IIH
Input High Current
SEL[1:0]
VDD = VIN = 3.465V
150
µA
IIL
Input Low Current
SEL[1:0]
VDD = 3.465V, VIN = 0V
-10
µA
Table 4C. Differential LVPECL Input DC Characteristics, VDD = 3.3V ± 5%, TA = -40°C to 85°C
Symbol
Parameter
Test Conditions
IIH
Input High Current
IIL
Input Low Current
VPP
Peak-to-Peak Voltage
VCMR
Common Mode Input Voltage;
NOTE 1
Minimum
Typical
Maximum
Units
150
µA
PCLK[0:3],
nPCLK[0:3]
VDD = VIN = 3.465V
PCLK[0:3]
VDD = 3.465V, VIN = 0V
-10
µA
nPCLK[0:3]
VDD = 3.465V, VIN = 0V
-150
µA
0.15
1.2
V
GND + 1.2
VDD
V
NOTE 1: Common mode input voltage is defined as VIH.
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Table 4D. LVDS DC Characteristics, VDD = 3.3V ± 5%, TA = -40°C to 85°C
Symbol
Parameter
VOD
Differential Output Voltage
∆VOD
VOD Magnitude Change
VOS
Offset Voltage
∆VOS
VOS Magnitude Change
Test Conditions
Minimum
Typical
Maximum
Units
247
380
454
mV
50
mV
1.375
V
50
mV
1.125
1.28
AC Electrical Characteristics
Table 5. AC Characteristics, VDD = 3.3V ± 5%, TA = -40°C to 85°C
Symbol
Parameter
fOUT
Output Frequency
tPD
Propagation Delay; NOTE 1
tjit(Ø)
Buffer Additive Phase Jitter,
RMS; Refer to Additive Phase
Jitter Section
tsk(pp)
Part-to-Part Skew; NOTE 2, 3
tsk(i)
Input Skew
tR / tF
Output Rise/Fall Time
MUXISOLATION
MUX Isolation; NOTE 4
Test Conditions
Minimum
Typical
Maximum
Units
2.5
GHz
295
470
700
ps
155.52MHz, Integration Range:
12kHz – 20MHz
20% to 80%
155.52MHz, VPP = 800mV
0.147
70
ps
300
ps
10
50
ps
150
250
ps
86
dB
NOTE: Electrical parameters are guaranteed over the specified ambient operating temperature range, which is established when the device is
mounted in a test socket with maintained transverse airflow greater than 500 lfpm. The device will meet specifications after thermal equilibrium
has been reached under these conditions.
All parameters measured ≤ 1.0GHz unless noted otherwise.
NOTE 1: Measured from the differential input crossing point to the differential output crossing point.
NOTE 2: Defined as skew between outputs on different devices operating at the same supply voltage, same temperature, same frequency and
with equal load conditions. Using the same type of inputs on each device, the outputs are measured at the differential cross points.
NOTE 3: This parameter is defined in accordance with JEDEC Standard 65.
NOTE 4: Q, nQ output measured differentially. See Parameter Measurement Information for MUX Isolation diagram.
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Additive Phase Jitter
The spectral purity in a band at a specific offset from the fundamental
compared to the power of the fundamental is called the dBc Phase
Noise. This value is normally expressed using a Phase noise plot
and is most often the specified plot in many applications. Phase noise
is defined as the ratio of the noise power present in a 1Hz band at a
specified offset from the fundamental frequency to the power value of
the fundamental. This ratio is expressed in decibels (dBm) or a ratio
SSB Phase Noise dBc/Hz
of the power in the 1Hz band to the power in the fundamental. When
the required offset is specified, the phase noise is called a dBc value,
which simply means dBm at a specified offset from the fundamental.
By investigating jitter in the frequency domain, we get a better
understanding of its effects on the desired application over the entire
time record of the signal. It is mathematically possible to calculate an
expected bit error rate given a phase noise plot.
Offset from Carrier Frequency (Hz)
As with most timing specifications, phase noise measurements has
issues relating to the limitations of the equipment. Often the noise
floor of the equipment is higher than the noise floor of the device. This
is illustrated above. The device meets the noise floor of what is
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
shown, but can actually be lower. The phase noise is dependent on
the input source and measurement equipment.
Measured using a Rohde & Schwarz SMA100 as the input source.
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©2012 Integrated Device Technology, Inc.
ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Parameter Measurement Information
VDD
SCOPE
Qx
VDD
3.3V±5%
POWER SUPPLY
+ Float GND –
nPCLK[0:3]
V
Cross Points
PP
V
CMR
PCLK[0:3]
nQx
GND
Differential Input Level
3.3V Output Load AC Test Circuit
Par t 1
nPCLK[0:3]
nQ
PCLK[0:3]
Q
nQ
nQ
Par t 2
Q
Q
tPD
tsk(pp)
Part-to-Part Skew
Propagation Delay
nPCLKx
Spectrum of Output Signal Q
PCLKx
MUX selects active
input clock signal
Amplitude (dB)
A0
nPCLKy
PCLKy
nQ
MUX_ISOL = A0 – A1
MUX selects static input
A1
Q
tPD2
tPD1
ƒ
(fundamental)
tsk(i)
Frequency
tsk(i) = |tPD1 - tPD2|
MUX Isolation
Input Skew
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ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Parameter Measurement Information, continued
VDD
nQ
80%
80%
out
VOD
20%
20%
Q
DC Input
LVDS
100
tF
tR
out
Differential Output Voltage Setup
Output Rise/Fall Time
VDD
out
DC Input
LVDS
out
VOS/∆ VOS
ä
Offset Voltage Setup
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Applications Information
Recommendations for Unused Input Pins
Inputs:
PCLK/nPCLK Inputs
For applications not requiring the use of a differential input, both the
PCLK and nPCLK pins can be left floating. Though not required, but
for additional protection, a 1kΩ resistor can be tied from PCLK to
ground.
Wiring the Differential Input to Accept Single-Ended Levels
Figure 1 shows how a differential input can be wired to accept single
ended levels. The reference voltage V1= VCC/2 is generated by the
bias resistors R1 and R2. The bypass capacitor (C1) is used to help
filter noise on the DC bias. This bias circuit should be located as close
to the input pin as possible. The ratio of R1 and R2 might need to be
adjusted to position the V1 in the center of the input voltage swing.
For example, if the input clock swing is 2.5V and VCC = 3.3V, R1 and
R2 value should be adjusted to set V1 at 1.25V. The values below are
for when both the single ended swing and VCC are at the same
voltage. This configuration requires that the sum of the output
impedance of the driver (Ro) and the series resistance (Rs) equals
the transmission line impedance. In addition, matched termination at
the input will attenuate the signal in half. This can be done in one of
two ways. First, R3 and R4 in parallel should equal the transmission
line impedance. For most 50Ω applications, R3 and R4 can be 100Ω.
The values of the resistors can be increased to reduce the loading for
slower and weaker LVCMOS driver. When using single-ended
signaling, the noise rejection benefits of differential signaling are
reduced. Even though the differential input can handle full rail
LVCMOS signaling, it is recommended that the amplitude be
reduced. The datasheet specifies a lower differential amplitude,
however this only applies to differential signals. For single-ended
applications, the swing can be larger, however VIL cannot be less
than -0.3V and VIH cannot be more than VCC + 0.3V. Though some
of the recommended components might not be used, the pads
should be placed in the layout. They can be utilized for debugging
purposes. The datasheet specifications are characterized and
guaranteed by using a differential signal.
VCC
VCC
Ro
VCC
R3
100
RS
R1
1K
Zo = 50 Ohm
+
V1
Driver
R4
Ro + Rs = Zo
VCC
Receiv er
-
100
C1
0.1uF
R2
1K
Figure 1. Recommended Schematic for Wiring a Differential Input to Accept Single-ended Levels
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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©2012 Integrated Device Technology, Inc.
ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
3.3V LVPECL Clock Input Interface
The input interfaces suggested here are examples only. If the driver
is from another vendor, use their termination recommendation.
Please consult with the vendor of the driver component to confirm the
driver termination requirements.
The PCLK /nPCLK accepts LVPECL, LVDS, CML and other
differential signals. Both VSWING and VOH must meet the VPP and
VCMR input requirements. Figures 2A to 2E show interface examples
for the PCLK/nPCLK input driven by the most common driver types.
3.3V
3.3V
3.3V
3.3V
3.3V
R1
50Ω
Zo = 50Ω
R2
50Ω
Zo = 50Ω
PCLK
R1
100Ω
PCLK
Zo = 50Ω
nPCLK
Zo = 50Ω
nPCLK
LVPECL
Input
CML
LVPECL
Input
CML Built-In Pullup
Figure 2B. PCLK/nPCLK Input Driven by a
Built-In Pullup CML Driver
Figure 2A. PCLK/nPCLK Input Driven by a CML Driver
3.3V
3.3V
3.3V
3.3V
R3
125Ω
3.3V
3.3V
R4
125Ω
Zo = 50Ω
R3
84
3.3V LVPECL
Zo = 50Ω
C1
Zo = 50Ω
C2
R4
84
PCLK
PCLK
Zo = 50Ω
nPCLK
nPCLK
LVPECL
Input
LVPECL
R1
84Ω
R2
84Ω
R5
100 - 200
R6
100 - 200
R1
125
R2
125
LVPECL
Input
Figure 2D. PCLK/nPCLK Input Driven by a
3.3V LVPECL Driver with AC Couple
Figure 2C. PCLK/nPCLK Input Driven by a
3.3V LVPECL Driver
3.3V
3.3V
Zo = 50Ω
PCLK
R1
100Ω
Zo = 50Ω
nPCLK
LVDS
LVPECL
Input
Figure 2E. PCLK/nPCLK Input Driven by a
3.3V LVDS Driver
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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©2012 Integrated Device Technology, Inc.
ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
LVDS Driver Termination
For a general LVDS interface, the recommended value for the
termination impedance (ZT) is between 90Ω and 132Ω. The actual
value should be selected to match the differential impedance (Z0) of
your transmission line. A typical point-to-point LVDS design uses a
100Ω parallel resistor at the receiver and a 100Ω differential
transmission-line environment. In order to avoid any
transmission-line reflection issues, the components should be
surface mounted and must be placed as close to the receiver as
possible. IDT offers a full line of LVDS compliant devices with two
types of output structures: current source and voltage source. The
LVDS
Driver
standard termination schematic as shown in Figure 3A can be used
with either type of output structure. Figure 3B, which can also be
used with both output types, is an optional termination with center tap
capacitance to help filter common mode noise. The capacitor value
should be approximately 50pF. If using a non-standard termination, it
is recommended to contact IDT and confirm if the output structure is
current source or voltage source type. In addition, since these
outputs are LVDS compatible, the input receiver’s amplitude and
common-mode input range should be verified for compatibility with
the output.
ZO ≈ ZT
ZT
LVDS
Receiver
Figure 3A. Standard Termination
LVDS
Driver
ZO ≈ ZT
C
ZT
2 LVDS
ZT Receiver
2
Figure 3B. Optional Termination
LVDS Termination
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
LVDS Power Considerations
This section provides information on power dissipation and junction temperature for the ICS854S054I.
Equations and example calculations are also provided.
1.
Power Dissipation.
The total power dissipation for the ICS854S054I is the sum of the core power plus the power dissipated in the load(s).
The following is the power dissipation for VDD = 3.3V + 5% = 3.465V, which gives worst case results.
NOTE: Please refer to Section 3 for details on calculating power dissipated in the load.
•
Power (core)MAX = VDD_MAX * IDD_MAX = 3.465V * 68mA = 235.62mW
2. Junction Temperature.
Junction temperature, Tj, is the temperature at the junction of the bond wire and bond pad directly affects the reliability of the device. The
maximum recommended junction temperature is 125°C. Limiting the internal transistor junction temperature, Tj, to 125°C ensures that the bond
wire and bond pad temperature remains below 125°C.
The equation for Tj is as follows: Tj = θJA * Pd_total + TA
Tj = Junction Temperature
θJA = Junction-to-Ambient Thermal Resistance
Pd_total = Total Device Power Dissipation (example calculation is in section 1 above)
TA = Ambient Temperature
In order to calculate junction temperature, the appropriate junction-to-ambient thermal resistance θJA must be used. Assuming no air flow and
a multi-layer board, the appropriate value is 100°C/W per Table 6 below.
Therefore, Tj for an ambient temperature of 85°C with all outputs switching is:
85°C + 0.236W * 100°C/W = 108.6°C. This is below the limit of 125°C.
This calculation is only an example. Tj will obviously vary depending on the number of loaded outputs, supply voltage, air flow and the type of
board (multi-layer).
Table 6. Thermal Resistance θJA for 16 Lead TSSOP, Forced Convection
θJA by Velocity
Meters per Second
Multi-Layer PCB, JEDEC Standard Test Boards
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
0
1
2.5
100°C/W
94.2°C/W
90.2°C/W
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©2012 Integrated Device Technology, Inc.
ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Reliability Information
Table 7. θJA vs. Air Flow Table for a 16 Lead TSSOP
θJA by Velocity
Meters per Second
Multi-Layer PCB, JEDEC Standard Test Boards
0
1
2.5
100°C/W
94.2°C/W
90.2°C/W
Transistor Count
The transistor count for ICS854S054I is: 450
This device is pin and function compatible, and a suggested replacement for ICS854054I.
Package Outline and Package Dimensions
Package Outline - G Suffix for 16 Lead TSSOP
Table 8. Package Dimensions
Symbol
N
A
A1
A2
b
c
D
E
E1
e
L
α
aaa
All Dimensions in Millimeters
Minimum
Maximum
16
1.20
0.05
0.15
0.80
1.05
0.19
0.30
0.09
0.20
4.90
5.10
6.40 Basic
4.30
4.50
0.65 Basic
0.45
0.75
0°
8°
0.10
Reference Document: JEDEC Publication 95, MO-153
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
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©2012 Integrated Device Technology, Inc.
ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
Ordering Information
Table 9. Ordering Information
Part/Order Number
854S054AGILF
854S054AGILFT
Marking
4S054AIL
4S054AIL
ICS854S054AGI REVISION A SEPTEMBER 28, 2012
Package
“Lead-Free” 16 Lead TSSOP
“Lead-Free” 16 Lead TSSOP
13
Shipping Packaging
Tube
Tape & Reel
Temperature
-40°C to 85°C
-40°C to 85°C
©2012 Integrated Device Technology, Inc.
ICS854S054I Data Sheet
4:1, DIFFERENTIAL-TO-LVDS CLOCK MULTIPLEXER
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including descriptions of product features and performance, is subject to change without notice. Performance specifications and the operating parameters of the described products are determined in the independent state and are not
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