TI LMK00334

LMK00334
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SNAS635 – DECEMBER 2013
LMK00334 4-Output PCIe/Gen1/Gen2/Gen3 Clock Buffer/Level Translator
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FEATURES
APPLICATIONS
•
•
1
2
•
•
•
•
•
•
•
•
3:1 Input Multiplexer
– Two Universal Inputs Operate up to 400
MHz and Accept LVPECL, LVDS, CML,
SSTL, HSTL, HCSL, or Single-Ended Clocks
– One Crystal Input Accepts a 10 to 40 MHz
Crystal or Single-Ended Clock
Two Banks with 2 Differential Outputs Each
– HCSL, or Hi-Z (Selectable)
– Additive RMS Phase Jitter for PCIe Gen3 at
100MHz:
– 30 fs RMS (typical)
High PSRR: -72 dBc at 156.25 MHz
LVCMOS Output with Synchronous Enable
Input
Pin-Controlled Configuration
VCC Core Supply: 3.3 V ± 5%
3 Independent VCCO Output Supplies: 3.3 V/2.5
V ± 5%
Industrial Temperature Range: -40°C to +85°C
32-lead WQFN (5 mm x 5 mm)
•
•
•
Clock Distribution and Level Translation for
ADCs, DACs, Multi-Gigabit Ethernet, XAUI,
Fibre Channel, SATA/SAS, SONET/SDH, CPRI,
High-Frequency Backplanes
Switches, Routers, Line Cards, Timing Cards
Servers, Computing, PCI Express (PCIe 3.0)
Remote Radio Units and Baseband Units
DESCRIPTION
The LMK00334 is a 4-output HCSL fanout buffer
intended for high-frequency, low-jitter clock/data
distribution and level translation. The input clock can
be selected from two universal inputs or one crystal
input. The selected input clock is distributed to two
banks of 2 HCSL outputs and one LVCMOS output.
The LVCMOS output has a synchronous enable input
for runt-pulse-free operation when enabled or
disabled. The LMK00334 operates from a 3.3 V core
supply and 3 independent 3.3 V/2.5 V output
supplies.
The LMK00334 provides high performance,
versatility, and power efficiency, making it ideal for
replacing fixed-output buffer devices while increasing
timing margin in the system.
FUNCTIONAL BLOCK DIAGRAM
CLKout_EN
CLKout_EN
1
2
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
All trademarks are the property of their respective owners.
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of the Texas
Instruments standard warranty. Production processing does not
necessarily include testing of all parameters.
Copyright © 2013, Texas Instruments Incorporated
LMK00334
SNAS635 – DECEMBER 2013
www.ti.com
VCC
REFout_EN
VCCOC
REFout
VCC
CLKin1
CLKin1*
NC
Connection Diagram
32
31
30
29
28
27
26
25
GND
1
24
GND
VCCOA
2
23
VCCOB
CLKoutA0
3
22
CLKoutB0
CLKoutA0*
4
21
CLKoutB0*
Top Down View
VCCOA
5
20
VCCOB
CLKoutA1
6
19
CLKoutB1
DAP
GND
10
11
12
13
14
15
16
CLKin_SEL1
9
CLKin0*
17
CLKin0
8
CLKin_SEL0
GND
OSCout
CLKoutB1*
OSCin
18
VCC
7
CLKout_EN
CLKoutA1*
Figure 1. 32-Pin Package
RTV0032A Package
Application Diagram
Mainboard
MAC
100MHz
Reference
Oscillator
PCI Express®
PHY
E.g.: XIO1100
Fan Out Buffer
E.g.: LMK00334
PCI Express®
fan-out switch
E.g.: XIO3130
Connector
PCI Express®
device
FPGA with
PCI Express®
Core
Add-In Card
Data
Clock
Figure 2. Example PCI Express Application
2
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Pin Descriptions (1)
Pin #
Pin Name(s)
Type
Description
DAP
DAP
GND
Die Attach Pad. Connect to the PCB ground plane for heat dissipation.
1, 8 17, 24
GND
GND
Ground
2, 5
VCCOA
PWR
Power supply for Bank A Output buffers. VCCOA operates from 3.3 V or 2.5
V. The VCCOA pins are internally tied together. Bypass with a 0.1 uF lowESR capacitor placed very close to each Vcco pin. (2)
3, 4
CLKoutA0, CLKoutA0*
O
Differential clock output A0.
6, 7
CLKoutA1, CLKoutA1*
O
Differential clock output A1.
9
CLKout_EN
I
Bank A and Bank B low active output buffer enable.
10
Vcc
PWR
11
OSCin
I
Input for crystal. Can also be driven by a XO, TCXO, or other external
single-ended clock.
12
OSCout
O
Output for crystal. Leave OSCout floating if OSCin is driven by a singleended clock.
13, 16
CLKin_SEL0, CLKin_SEL1
I
Clock input selection pins
(1)
(2)
(3)
(3)
Power supply for Core and Input Buffer blocks. The Vcc supply operates
from 3.3 V. Bypass with a 0.1 uF low-ESR capacitor placed very close to
each Vcc pin.
(3)
14, 15
CLKin0, CLKin0*
I
Universal clock input 0 (differential/single-ended)
18, 19
CLKoutB1*, CLKoutB1
O
Differential clock output B1.
20, 23
VCCOB
PWR
21, 22
CLKoutB0*, CLKoutB0
O
Differential clock output B0.
25
NC
—
Not connected internally. Pin may be floated, grounded, or otherwise tied to
any potential within the Supply Voltage range stated in the Absolute
Maximum Ratings.
26, 27
CLKin1*, CLKin1
I
Universal clock input 1 (differential/single-ended)
29
REFout
O
LVCMOS reference output. Enable output by pulling REFout_EN pin high.
30
VCCOC
PWR
Power supply for REFout buffer. VCCOC operates from 3.3 V or 2.5 V.
Bypass with a 0.1 uF low-ESR capacitor placed very close to each Vcco
pin. (2)
31
REFout_EN
I
REFout enable input. Enable signal is internally synchronized to selected
clock input. (3)
Power supply for Bank B Output buffers. VCCOB operates from 3.3 V or 2.5
V. The VCCOB pins are internally tied together. Bypass with a 0.1 uF lowESR capacitor placed very close to each Vcco pin. (2)
Any unused output pins should be left floating with minimum copper length (see note in Clock Outputs), or properly terminated if
connected to a transmission line, or disabled/Hi-Z if possible. See Clock Outputs for output configuration and Termination and Use of
Clock Drivers for output interface and termination techniques.
The output supply voltages or pins (VCCOA, VCCOB, and VCCOC) will be called VCCO in general when no distinction is needed, or when the
output supply can be inferred from the output bank/type.
CMOS control input with internal pull-down resistor.
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Functional Description
The LMK00334 is a 4-output HCSL clock fanout buffer with low additive jitter that can operate up to 400 MHz. It
features a 3:1 input multiplexer with an optional crystal oscillator input, two banks of 2 HCSL outputs, one
LVCMOS output, and 3 independent output buffer supplies. The input selection and output buffer modes are
controlled via pin strapping. The device is offered in a 32-pin WQFN package and leverages much of the highspeed, low-noise circuit design employed in the LMK04800 family of clock conditioners.
VCC and VCCO Power Supplies
The LMK00334 has separate 3.3 V core supply (VCC) and 3 independent 3.3 V/2.5 V output power supplies
(VCCOA, VCCOB, VCCOC). Output supply operation at 2.5 V enables lower power consumption and output-level
compatibility with 2.5 V receiver devices. The output levels for HCSL are relatively constant over the specified
Vcco range. Refer to Power Supply and Thermal Considerations for additional supply related considerations,
such as power dissipation, power supply bypassing, and power supply ripple rejection (PSRR).
NOTE
Care should be taken to ensure the Vcco voltages do not exceed the Vcc voltage to
prevent turning-on the internal ESD protection circuitry.
Clock Inputs
The input clock can be selected from CLKin0/CLKin0*, CLKin1/CLKin1*, or OSCin. Clock input selection is
controlled using the CLKin_SEL[1:0] inputs as shown in Table 1. Refer to Driving the Clock Inputs for clock input
requirements. When CLKin0 or CLKin1 is selected, the crystal circuit is powered down. When OSCin is selected,
the crystal oscillator circuit will start-up and its clock will be distributed to all outputs. Refer to Crystal Interface for
more information. Alternatively, OSCin may be driven by a single-ended clock (up to 250 MHz) instead of a
crystal.
Table 1. Input Selection
CLKin_SEL1
CLKin_SEL0
Selected Input
0
0
CLKin0, CLKin0*
0
1
CLKin1, CLKin1*
1
X
OSCin
Table 2 shows the output logic state vs. input state when either CLKin0/CLKin0* or CLKin1/CLKin1* is selected.
When OSCin is selected, the output state will be an inverted copy of the OSCin input state.
Table 2. CLKin Input vs. Output States
4
State of
Selected CLKin
State of
Enabled Outputs
CLKinX and CLKinX* inputs floating
Logic low
CLKinX and CLKinX* inputs shorted together
Logic low
CLKin logic low
Logic low
CLKin logic high
Logic high
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Clock Outputs
The HCSL output buffer for both Bank A and B outputs are can be disabled to Hi-Z using the CLKout_EN [1:0] as
shown in Table 3. For applications where all differential outputs are not needed, any unused output pin should be
left floating with a minimum copper length (see note below) to minimize capacitance and potential coupling and
reduce power consumption. If all differential outputs are not used, it is recommended to disable (Hi-Z) the banks
to reduce power. Refer to Termination and Use of Clock Drivers for more information on output interface and
termination techniques.
NOTE
For best soldering practices, the minimum trace length for any unused pin should extend
to include the pin solder mask. This way during reflow, the solder has the same copper
area as connected pins. This allows for good, uniform fillet solder joints helping to keep
the IC level during reflow.
Table 3. Differential Output Buffer Type Selection
CLKoutX Buffer Type
(Bank A and B)
CLKout_EN
0
HCSL
1
Disabled (Hi-Z)
Reference Output
The reference output (REFout) provides a LVCMOS copy of the selected input clock. The LVCMOS output high
level is referenced to the Vcco voltage. REFout can be enabled or disabled using the enable input pin,
REFout_EN, as shown in Table 4.
Table 4. Reference Output Enable
REFout_EN
REFout State
0
Disabled (Hi-Z)
1
Enabled
The REFout_EN input is internally synchronized with the selected input clock by the SYNC block. This
synchronizing function prevents glitches and runt pulses from occurring on the REFout clock when enabled or
disabled. REFout will be enabled within 3 cycles (tEN) of the input clock after REFout_EN is toggled high. REFout
will be disabled within 3 cycles (tDIS) of the input clock after REFout_EN is toggled low.
When REFout is disabled, the use of a resistive loading can be used to set the output to a predetermined level.
For example, if REFout is configured with a 1 kΩ load to ground, then the output will be pulled to low when
disabled.
ABSOLUTE MAXIMUM RATINGS (1) (2) (3)
Parameter
Ratings
Units
VCC, VCCO
-0.3 to 3.6
V
VIN
-0.3 to (VCC + 0.3)
V
TSTG
-65 to +150
°C
Lead Temperature (solder 4 s)
TL
+260
°C
Junction Temperature
TJ
+150
°C
Supply Voltages
Input Voltage
Storage Temperature Range
(1)
(2)
(3)
Symbol
Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for
which the device is intended to be functional, but do not ensure specific performance limits. For ensured specifications and test
conditions, see ELECTRICAL CHARACTERISTICS. The ensured specifications apply only to the test conditions listed.
This device is a high-performance integrated circuit with an ESD rating up to 2 kV Human Body Model, up to 150 V Machine Model, and
up to 750 V Charged Device Model and is ESD sensitive. Handling and assembly of this device should only be done at ESD-free
workstations.
If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/Distributors for availability and
specifications.
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RECOMMENDED OPERATING CONDITIONS
Symbol
Min
Typ
Max
Units
Ambient Temperature Range
Parameter
TA
-40
25
85
°C
Junction Temperature
TJ
125
°C
Core Supply Voltage Range
Output Supply Voltage Range
(1)
(2)
(1) (2)
VCC
3.15
3.3
3.45
V
VCCO
3.3 – 5%
2.5 – 5%
3.3
2.5
3.3 + 5%
2.5 + 5%
V
The output supply voltages or pins (VCCOA, VCCOB, and VCCOC) will be called VCCO in general when no distinction is needed, or when the
output supply can be inferred from the output bank/type.
Vcco for any output bank should be less than or equal to Vcc (Vcco ≤ Vcc).
PACKAGE THERMAL RESISTANCE
θJA
Package
32-Lead WQFN
(1)
6
(1)
38.1 °C/W
θJC
(DAP)
7.2 °C/W
Specification assumes 5 thermal vias connect the die attach pad (DAP) to the embedded copper plane on the 4-layer JEDEC board.
These vias play a key role in improving the thermal performance of the package. It is recommended that the maximum number of vias
be used in the board layout.
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ELECTRICAL CHARACTERISTICS
Unless otherwise specified: Vcc = 3.3 V ± 5%, Vcco = 3.3 V ± 5%, 2.5 V ± 5%, -40 °C ≤ TA ≤ 85 °C, CLKin driven
differentially, input slew rate ≥ 3 V/ns. Typical values represent most likely parametric norms at Vcc = 3.3 V, Vcco = 3.3 V, TA
= 25 °C, and at the Recommended Operation Conditions at the time of product characterization and are not ensured. (1)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
Current Consumption (2)
ICC_CORE
Core Supply Current, All Outputs
Disabled
CLKinX selected
8.5
10.5
mA
OSCin selected
10
13.5
mA
ICC_HCSL
50
58.5
mA
ICC_CMOS
3.5
5.5
mA
65
81.5
mA
Vcco = 3.3 V ±5%
9
10
mA
Vcco = 2.5V ± 5%
7
8
mA
ICCO_HCSL
Additive Output Supply Current,
HCSL Banks Enabled
Includes Output Bank Bias and Load Currents
for both banks, RT = 50 Ω on all outputs
ICCO_CMOS
Additive Output Supply Current,
LVCMOS Output Enabled
PSRRHCSL
Ripple-Induced Phase Spur Level (3)
Differential HCSL Output
VIH
High-Level Input Voltage
1.6
Vcc
VIL
Low-Level Input Voltage
GND
0.4
V
IIH
High-Level Input Current
VIH = Vcc, Internal pull-down resistor
50
μA
IIL
Low-Level Input Current
VIL = 0 V, Internal pull-down resistor
200 MHz, CL = 5 pF
Power Supply Ripple Rejection (PSRR)
156.25 MHz
-72
312.5 MHz
-63
dBc
CMOS Control Inputs (CLKin_SELn, CLKout_TYPEn, REFout_EN)
-5
V
μA
0.1
Clock Inputs (CLKin0/CLKin0*, CLKin1/CLKin1*)
fCLKin
VIHD
(2)
(3)
(4)
(5)
DC
Differential Input High Voltage
VILD
Differential Input Low Voltage
VID
Differential Input Voltage Swing (5)
VCMD
(1)
Input Frequency Range
Functional up to 400 MHz
Output frequency range and timing specified
per output type (refer to LVCMOS output
specifications)
(4)
CLKin driven differentially
Differential Input CMD Common
Mode Voltage
VIH
Single-Ended Input IH High Voltage
VIL
Single-Ended Input IL Low Voltage
(4)
VI_SE
Single-Ended Input Voltage Swing
VCM
Single-Ended Input CM Common
Mode Voltage
400
MHz
Vcc
V
GND
V
0.15
1.3
VID = 150 mV
0.25
Vcc 1.2
VID = 350 mV
0.25
Vcc 1.1
VID = 800 mV
0.25
Vcc 0.9
CLKinX driven single-ended (AC or DC
coupled), CLKinX* AC coupled to GND or
externally biased within VCM range
GND
VCC
V
V
V
V
0.3
2
Vpp
0.25
VCC 1.2
V
The output supply voltages or pins (VCCOA, VCCOB, and VCCOC) will be called VCCO in general when no distinction is needed, or when the
output supply can be inferred from the output bank/type.
See Power Supply and Thermal Considerations for more information on current consumption and power dissipation calculations.
Power supply ripple rejection, or PSRR, is defined as the single-sideband phase spur level (in dBc) modulated onto the clock output
when a single-tone sinusoidal signal (ripple) is injected onto the Vcco supply. Assuming no amplitude modulation effects and small index
modulation, the peak-to-peak deterministic jitter (DJ) can be calculated using the measured single-sideband phase spur level (PSRR) as
follows: DJ (ps pk-pk) = [ (2 * 10(PSRR / 20)) / (π * fCLK) ] * 1E12
Specification is ensured by characterization and is not tested in production.
See Differential Voltage Measurement Terminology for definition of VID and VOD voltages.
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ELECTRICAL CHARACTERISTICS (continued)
Unless otherwise specified: Vcc = 3.3 V ± 5%, Vcco = 3.3 V ± 5%, 2.5 V ± 5%, -40 °C ≤ TA ≤ 85 °C, CLKin driven
differentially, input slew rate ≥ 3 V/ns. Typical values represent most likely parametric norms at Vcc = 3.3 V, Vcco = 3.3 V, TA
= 25 °C, and at the Recommended Operation Conditions at the time of product characterization and are not ensured. (1)
SYMBOL
ISOMUX
PARAMETER
CONDITIONS
fOFFSET > 50 kHz,
PCLKinX = 0 dBm
Mux Isolation, CLKin0 to CLKin1
MIN
TYP
fCLKin0 = 100 MHz
-84
fCLKin0 = 200 MHz
-82
fCLKin0 = 500 MHz
-71
fCLKin0 = 1000 MHz
-65
MAX
UNIT
dBc
Crystal Interface (OSCin, OSCout)
External Clock Frequency Range (6)
OSCin driven single-ended, OSCout floating
FXTAL
Crystal Frequency Range
Fundamental mode crystal ESR ≤ 200 Ω (10
to 30 MHz) ESR ≤ 125 Ω (30 to 40 MHz) (7)
CIN
OSCin Input Capacitance
fCLKout
Output Frequency Range (6)
FCLK
10
250
MHz
40
MHz
1
pF
HCSL Outputs (CLKoutAn/CLKoutAn*, CLKoutBn/CLKoutBn*)
RL = 50 Ω to GND, CL ≤ 5 pF
JitterADD_PCle
Additive RMS Phase Jitter for PCIe
3.0 (6)
PCIe Gen 3, PLL BW
= 2–5 MHz, CDR = 10
MHz
JitterADD
Additive RMS Jitter Integration
Bandwidth 1 MHz to 20 MHz (8)
Vcco = 3.3 V, RT = 50
Ω to GND
Noise Floor
Noise Floor fOFFSET ≥ 10 MHz
(9) (10)
Vcco = 3.3 V, RT = 50
Ω to GND
DC
CLKin: 100 MHz,
Slew rate ≥ 0.6 V/ns
0.03
CLKin: 100 MHz,
Slew rate ≥ 3 V/ns
77
CLKin: 156.25 MHz,
Slew rate ≥ 2.7 V/ns
86
CLKin: 100 MHz,
Slew rate ≥ 3 V/ns
-161.3
CLKin: 156.25 MHz,
Slew rate ≥ 2.7 V/ns
-156.3
50% input clock duty cycle
45
VOH
Output High Voltage
TA = 25 °C, DC Measurement, RT = 50 Ω to
GND
520
-150
250
VCROSS
Absolute Crossing Voltage (6) (11)
ΔVCROSS
Total Variation of VCROSS (6) (11)
tR
Output Rise Time 20% to
80% (11) (12)
tF
Output Fall Time 80% to 20% (11) (12)
ps
55
%
810
920
mV
0.5
150
mV
350
460
mV
140
mV
300
500
ps
300
500
ps
RL = 50 Ω to GND, CL ≤ 5 pF
250 MHz, Uniform transmission line up to 10
in. with 50-Ω characteristic impedance, RL =
50 Ω to GND, CL ≤ 5 pF
0.15
dBc/Hz
Duty Cycle (6)
Output Low Voltage
MHz
fs
DUTY
VOL
400
(6)
(7)
Specification is ensured by characterization and is not tested in production.
The ESR requirements stated must be met to ensure that the oscillator circuitry has no startup issues. However, lower ESR values for
the crystal may be necessary to stay below the maximum power dissipation (drive level) specification of the crystal. Refer to Crystal
Interface for crystal drive level considerations.
(8) For the 100 MHz and 156.25 MHz clock input conditions, Additive RMS Jitter (JADD) is calculated using Method #1: JADD = SQRT(JOUT2
- JSOURCE2), where JOUT is the total RMS jitter measured at the output driver and JSOURCE is the RMS jitter of the clock source applied to
CLKin. For the 625 MHz clock input condition, Additive RMS Jitter is approximated using Method #2: JADD = SQRT(2*10dBc/10) /
(2*π*fCLK), where dBc is the phase noise power of the Output Noise Floor integrated from 1 to 20 MHz bandwidth. The phase noise
power can be calculated as: dBc = Noise Floor + 10*log10(20 MHz - 1 MHz). The additive RMS jitter was approximated for 625 MHz
using Method #2 because the RMS jitter of the clock source was not sufficiently low enough to allow practical use of Method #1. Refer
to the “Noise Floor vs. CLKin Slew Rate” and “RMS Jitter vs. CLKin Slew Rate” plots in TYPICAL CHARACTERISTICS.
(9) The noise floor of the output buffer is measured as the far-out phase noise of the buffer. Typically this offset is ≥ 10 MHz, but for lower
frequencies this measurement offset can be as low as 5 MHz due to measurement equipment limitations.
(10) Phase noise floor will degrade as the clock input slew rate is reduced. Compared to a single-ended clock, a differential clock input
(LVPECL, LVDS) will be less susceptible to degradation in noise floor at lower slew rates due to its common mode noise rejection.
However, it is recommended to use the highest possible input slew rate for differential clocks to achieve optimal noise floor performance
at the device outputs.
(11) AC timing parameters for HCSL or CMOS are dependent on output capacitive loading.
(12) Parameter is specified by design, not tested in production.
8
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ELECTRICAL CHARACTERISTICS (continued)
Unless otherwise specified: Vcc = 3.3 V ± 5%, Vcco = 3.3 V ± 5%, 2.5 V ± 5%, -40 °C ≤ TA ≤ 85 °C, CLKin driven
differentially, input slew rate ≥ 3 V/ns. Typical values represent most likely parametric norms at Vcc = 3.3 V, Vcco = 3.3 V, TA
= 25 °C, and at the Recommended Operation Conditions at the time of product characterization and are not ensured. (1)
SYMBOL
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNIT
LVCMOS Output (REFout)
fCLKout
Output Frequency Range (13)
JitterADD
Additive RMS Jitter Integration
Bandwidth 1 MHz to 20 MHz (14)
Noise Floor
DUTY
Noise Floor fOFFSET ≥ 10 MHz (15)
Output High Voltage
VOL
Output Low Voltage
IOL
tR
(16)
Duty Cycle (13)
VOH
IOH
CL ≤ 5 pF
DC
250
Vcco = 3.3 V, CL ≤ 5
pF
100 MHz, Input Slew
rate ≥ 3 V/ns
95
fs
Vcco = 3.3 V, CL ≤ 5
pF
100 MHz, Input Slew
rate ≥ 3 V/ns
-159.3
dBc/Hz
50% input clock duty cycle
45
1 mA load
Vcco 0.1
55
Vo = Vcco / 2
Output Low Current (Sink)
Output Rise Time 20% to 80% (17)
(18)
tF
Output Fall Time 80% to 20% (19) (18)
tEN
Output Enable Time (19)
tDIS
Output Disable Time (19)
Vcco = 3.3 V
28
Vcco = 2.5 V
20
Vcco = 3.3 V
28
Vcco = 2.5 V
20
250 MHz, Uniform transmission line up to 10
in. with 50-Ω characteristic impedance, RL =
50 Ω to GND, CL ≤ 5 pF
%
V
0.1
Output High Current (Source)
MHz
V
mA
mA
225
400
225
400
ps
3
cycles
3
cycles
ps
CL ≤ 5 pF
ps
Propagation Delay and Output Skew
tPD_HCSL
Propagation Delay CLKin-to-HCSL
(17) (18)
tPD_CMOS
Propagation Delay CLKin-toLVCMOS (17) (18)
tSK(O)
Output Skew (20) (17) (13)
tSK(PP)
Part-to-Part Output Skew
(17) (18) (20)
RT = 50 Ω to GND, CL ≤ 5 pF
CL ≤ 5 pF
295
590
885
Vcco = 3.3 V
900
1475
2300
Vcco = 2.5 V
1000
1550
2700
30
50
ps
80
120
ps
Skew specified between any two CLKouts.
Load conditions are the same as propagation
delay specifications.
ps
(13) Specification is ensured by characterization and is not tested in production.
(14) For the 100 MHz and 156.25 MHz clock input conditions, Additive RMS Jitter (JADD) is calculated using Method #1: JADD = SQRT(JOUT2
- JSOURCE2), where JOUT is the total RMS jitter measured at the output driver and JSOURCE is the RMS jitter of the clock source applied to
CLKin. For the 625 MHz clock input condition, Additive RMS Jitter is approximated using Method #2: JADD = SQRT(2*10dBc/10) /
(2*π*fCLK), where dBc is the phase noise power of the Output Noise Floor integrated from 1 to 20 MHz bandwidth. The phase noise
power can be calculated as: dBc = Noise Floor + 10*log10(20 MHz - 1 MHz). The additive RMS jitter was approximated for 625 MHz
using Method #2 because the RMS jitter of the clock source was not sufficiently low enough to allow practical use of Method #1. Refer
to the “Noise Floor vs. CLKin Slew Rate” and “RMS Jitter vs. CLKin Slew Rate” plots in TYPICAL CHARACTERISTICS.
(15) The noise floor of the output buffer is measured as the far-out phase noise of the buffer. Typically this offset is ≥ 10 MHz, but for lower
frequencies this measurement offset can be as low as 5 MHz due to measurement equipment limitations.
(16) Phase noise floor will degrade as the clock input slew rate is reduced. Compared to a single-ended clock, a differential clock input
(LVPECL, LVDS) will be less susceptible to degradation in noise floor at lower slew rates due to its common mode noise rejection.
However, it is recommended to use the highest possible input slew rate for differential clocks to achieve optimal noise floor performance
at the device outputs.
(17) AC timing parameters for HCSL or CMOS are dependent on output capacitive loading.
(18) Parameter is specified by design, not tested in production.
(19) Output Enable Time is the number of input clock cycles it takes for the output to be enabled after REFout_EN is pulled high. Similarly,
Output Disable Time is the number of input clock cycles it takes for the output to be disabled after REFout_EN is pulled low. The
REFout_EN signal should have an edge transition much faster than that of the input clock period for accurate measurement.
(20) Output skew is the propagation delay difference between any two outputs with identical output buffer type and equal loading while
operating at the same supply voltage and temperature conditions.
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MEASUREMENT DEFINITIONS
Differential Voltage Measurement Terminology
The differential voltage of a differential signal can be described by two different definitions causing confusion
when reading datasheets or communicating with other engineers. This section will address the measurement and
description of a differential signal so that the reader will be able to understand and discern between the two
different definitions when used.
The first definition used to describe a differential signal is the absolute value of the voltage potential between the
inverting and non-inverting signal. The symbol for this first measurement is typically VID or VOD depending on if
an input or output voltage is being described.
The second definition used to describe a differential signal is to measure the potential of the non-inverting signal
with respect to the inverting signal. The symbol for this second measurement is VSS and is a calculated
parameter. Nowhere in the IC does this signal exist with respect to ground, it only exists in reference to its
differential pair. VSS can be measured directly by oscilloscopes with floating references, otherwise this value can
be calculated as twice the value of VOD as described in the first description.
Figure 3 illustrates the two different definitions side-by-side for inputs and Figure 4 illustrates the two different
definitions side-by-side for outputs. The VID (or VOD) definition show the DC levels, VIH and VOL (or VOH and VOL),
that the non-inverting and inverting signals toggle between with respect to ground. VSS input and output
definitions show that if the inverting signal is considered the voltage potential reference, the non-inverting signal
voltage potential is now increasing and decreasing above and below the non-inverting reference. Thus the peakto-peak voltage of the differential signal can be measured.
VID and VOD are often defined as volts (V) and VSS is often defined as volts peak-to-peak (VPP).
VID Definition
VSS Definition for Input
Non-Inverting Clock
VIH
VCM
VSS
VID
VIL
Inverting Clock
VSS = 2· VID
VID = | VIH ± VIL |
GND
Figure 3. Two Different Definitions for Differential Input Signals
VOD Definition
VSS Definition for Output
Non-Inverting Clock
VOH
VOS
VOL
VSS
VOD
Inverting Clock
VOD = | VOH - VOL |
VSS = 2· VOD
GND
Figure 4. Two Different Definitions for Differential Output Signals
Refer to Application Note AN-912 (literature number SNLA036), Common Data Transmission Parameters and
their Definitions, for more information.
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TYPICAL CHARACTERISTICS
Unless otherwise specified: Vcc = 3.3 V, Vcco = 3.3 V, TA = 25 °C, CLKin driven differentially, input slew rate ≥ 3 V/ns.
HCSL Output Swing @ 250 MHz
LVCMOS Output Swing @ 250 MHz
1.0
1.00
OUTPUT SWING (V)
OUTPUT SWING (V)
0.8
0.6
0.4
0.2
0.0
0.25
0.00
-0.25
-0.50
-1.00
0
1
2
3
TIME (ns)
4
5
0
1
2
3
4
TIME (ns)
5
6
Figure 5.
Figure 6.
Noise Floor vs. CLKin Slew Rate @ 100 MHz
-140
Noise Floor vs. CLKin Slew Rate @ 156.25 MHz
-135
-145
HCSL
LVCMOS
CLKin Source
Fclk=100 MHz
Foffset=20 MHz
-150
-155
-160
-16516
NOISE FLOOR (dBc/Hz)
NOISE FLOOR (dBc/Hz)
0.50
-0.75
-0.2
-140
HCSL
CLKin Source
Fclk=156.25 MHz
Foffset=20 MHz
-145
-150
-155
-160
-165
-170
0.5
1.0
1.5
2.0
2.5
3.0
3.5
DIFFERENTIAL INPUT SLEW RATE (V/ns)
Figure 7.
0.5
1.0
1.5
2.0
2.5
3.0
3.5
DIFFERENTIAL INPUT SLEW RATE (V/ns)
Figure 8.
RMS Jitter vs. CLKin Slew Rate @ 100 MHz
400
RMS Jitter vs. CLKin Slew Rate @ 156.25 MHz
500
300
HCSL
LVCMOS
CLKin Source
450
Fclk=100 MHz
Int. BW=1-20 MHz
400
RMS JITTER (fs)
350
RMS JITTER (fs)
Vcco=3.3 V, AC coupled, 50load
Vcco=2.5 V, AC coupled, 50load
0.75
250
200
150
100
HCSL
CLKin Source
Fclk=156.25 MHz
Int. BW=1-20 MHz
350
300
250
200
150
100
50
50
0
0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
DIFFERENTIAL INPUT SLEW RATE (V/ns)
Figure 9.
0.5
1.0
1.5
2.0
2.5
3.0
3.5
DIFFERENTIAL INPUT SLEW RATE (V/ns)
Figure 10.
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TYPICAL CHARACTERISTICS (continued)
-60
-65
-70
-75
-80
-85
-90
.1
CLKout PROPAGATION DELAY (ps)
850
750
650
1
RIPPLE FREQUENCY (MHz)
Figure 11.
PSRR vs. Ripple Frequency @ 312.5 MHz
-50
-55
Right Y-axis plot
1850
1750
1650
450
1550
350
1450
250
1350
-25
0
25
50
75
TEMPERATURE (°C)
-70
-75
-80
-85
-90
.1
1
RIPPLE FREQUENCY (MHz)
Figure 12.
10
HCSL Phase Noise @ 100 MHz
100
Figure 13.
12
Fclk=312.5 MHz
Vcco Ripple=100 mVpp
-65
Propagation Delay vs. Temperature
1950
HCSL (0.35 ps/°C)
LVCMOS (2.2 ps/°C)
HCSL
-60
10
550
-50
RIPPLE INDUCED SPUR LEVEL (dBc)
PSRR vs. Ripple Frequency @ 156.25 MHz
-50
Fclk=156.25 MHz
-55
Vcco Ripple=100 mVpp
HCSL
REFout PROPAGATION DELAY (ps)
RIPPLE INDUCED SPUR LEVEL (dBc)
Unless otherwise specified: Vcc = 3.3 V, Vcco = 3.3 V, TA = 25 °C, CLKin driven differentially, input slew rate ≥ 3 V/ns.
Figure 14.
(1)
The typical RMS jitter values in the plots show the total output RMS jitter (JOUT) for each output buffer type and the
source clock RMS jitter (JSOURCE). From these values, the Additive RMS Jitter can be calculated as: JADD =
SQRT(JOUT2 - JSOURCE2).
(2)
20 MHz crystal characteristics: Abracon ABL series, AT cut, CL = 18 pF , C0 = 4.4 pF measured (7 pF max), ESR =
8.5 Ω measured (40 Ω max), and Drive Level = 1 mW max (100 µW typical).
(3)
40 MHz crystal characteristics: Abracon ABLS2 series, AT cut, CL = 18 pF , C0 = 5 pF measured (7 pF max), ESR =
5 Ω measured (40 Ω max), and Drive Level = 1 mW max (100 µW typical).
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TYPICAL CHARACTERISTICS (continued)
Unless otherwise specified: Vcc = 3.3 V, Vcco = 3.3 V, TA = 25 °C, CLKin driven differentially, input slew rate ≥ 3 V/ns.
CRYSTAL POWER DISSIPATION (W)
Crystal Power Dissipation vs. RLIM
200
20 MHz Crystal
40 MHz Crystal
175
150
125
100
75
50
25
0
0
500 1k 1.5k 2k 2.5k 3k 3.5k 4k
RLIM()
Figure 15.
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APPLICATION INFORMATION
Driving the Clock Inputs
The LMK00334 has two universal inputs (CLKin0/CLKin0* and CLKin1/CLKin1*) that can accept DC-coupled
3.3V/2.5V LVPECL, LVDS, CML, SSTL, and other differential and single-ended signals that meet the input
requirements specified in ELECTRICAL CHARACTERISTICS. The device can accept a wide range of signals
due to its wide input common mode voltage range (VCM ) and input voltage swing (VID) / dynamic range. For 50%
duty cycle and DC-balanced signals, AC coupling may also be employed to shift the input signal to within the
VCM range. Refer to Termination and Use of Clock Drivers for signal interfacing and termination techniques.
To achieve the best possible phase noise and jitter performance, it is mandatory for the input to have high slew
rate of 3 V/ns (differential) or higher. Driving the input with a lower slew rate will degrade the noise floor and jitter.
For this reason, a differential signal input is recommended over single-ended because it typically provides higher
slew rate and common-mode-rejection. Refer to the “Noise Floor vs. CLKin Slew Rate” and “RMS Jitter vs. CLKin
Slew Rate” plots in TYPICAL CHARACTERISTICS.
While it is recommended to drive the CLKin/CLKin* pair with a differential signal input, it is possible to drive it
with a single-ended clock provided it conforms to the Single-Ended Input specifications for CLKin pins listed in
the ELECTRICAL CHARACTERISTICS. For large single-ended input signals, such as 3.3V or 2.5V LVCMOS, a
50 Ω load resistor should be placed near the input for signal attenuation to prevent input overdrive as well as for
line termination to minimize reflections. Again, the single-ended input slew rate should be as high as possible to
minimize performance degradation. The CLKin input has an internal bias voltage of about 1.4 V, so the input can
be AC coupled as shown in Figure 16. The output impedance of the LVCMOS driver plus Rs should be close to
50 Ω to match the characteristic impedance of the transmission line and load termination.
RS 0.1 PF
0.1 PF
50:Trace
50:
CMOS
Driver
LMK
Input
0.1 PF
Figure 16. Single-Ended LVCMOS Input, AC Coupling
A single-ended clock may also be DC coupled to CLKinX as shown in Figure 17. A 50-Ω load resistor should be
placed near the CLKin input for signal attenuation and line termination. Because half of the single-ended swing of
the driver (VO,PP / 2) drives CLKinX, CLKinX* should be externally biased to the midpoint voltage of the
attenuated input swing ((VO,PP / 2) × 0.5). The external bias voltage should be within the specified input common
voltage (VCM) range. This can be achieved using external biasing resistors in the kΩ range (RB1 and RB2) or
another low-noise voltage reference. This will ensure the input swing crosses the threshold voltage at a point
where the input slew rate is the highest.
CMOS
Driver
VO,PP
Rs
VO,PP/2
VCC
50:Trace
VBB ~ (VO,PP/2) x 0.5
50:
LMK
Input
RB1
VCC
RB2
0.1 PF
Figure 17. Single-Ended LVCMOS Input, DC Coupling
with Common Mode Biasing
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If the crystal oscillator circuit is not used, it is possible to drive the OSCin input with an single-ended external
clock as shown in Figure 18. The input clock should be AC coupled to the OSCin pin, which has an internallygenerated input bias voltage, and the OSCout pin should be left floating. While OSCin provides an alternative
input to multiplex an external clock, it is recommended to use either universal input (CLKinX) since it offers
higher operating frequency, better common mode and power supply noise rejection, and greater performance
over supply voltage and temperature variations.
0.1 PF
50:Trace
OSCin
OSCout
LMK00301
RS 0.1 PF
50:
CMOS
Driver
Figure 18. Driving OSCin with a Single-Ended Input
Crystal Interface
C1
XTAL
RLIM
OSCin
OSCout
LMK00301
The LMK00334 has an integrated crystal oscillator circuit that supports a fundamental mode, AT-cut crystal. The
crystal interface is shown in Figure 19.
C2
Figure 19. Crystal Interface
The load capacitance (CL) is specific to the crystal, but usually on the order of 18 - 20 pF. While CL is specified
for the crystal, the OSCin input capacitance (CIN = 1 pF typical) of the device and PCB stray capacitance (CSTRAY
~ 1~3 pF) can affect the discrete load capacitor values, C1 and C2.
For the parallel resonant circuit, the discrete capacitor values can be calculated as follows:
CL = (C1 * C2) / (C1 + C2) + CIN + CSTRAY
(1)
Typically, C1 = C2 for optimum symmetry, so Equation 1 can be rewritten in terms of C1 only:
CL = C12 / (2 * C1) + CIN + CSTRAY
(2)
Finally, solve for C1:
C1 = (CL - CIN - CSTRAY)*2
(3)
ELECTRICAL CHARACTERISTICS provides crystal interface specifications with conditions that ensure start-up
of the crystal, but it does not specify crystal power dissipation. The designer will need to ensure the crystal power
dissipation does not exceed the maximum drive level specified by the crystal manufacturer. Overdriving the
crystal can cause premature aging, frequency shift, and eventual failure. Drive level should be held at a sufficient
level necessary to start-up and maintain steady-state operation.
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The power dissipated in the crystal, PXTAL, can be computed by:
PXTAL = IRMS2 * RESR*(1 + C0/CL)2
where
•
•
•
•
IRMS is the RMS current through the crystal.
RESR is the max. equivalent series resistance specified for the crystal
CL is the load capacitance specified for the crystal
C0 is the min. shunt capacitance specified for the crystal
(4)
IRMS can be measured using a current probe (e.g. Tektronix CT-6 or equivalent) placed on the leg of the crystal
connected to OSCout with the oscillation circuit active.
As shown in Figure 19, an external resistor, RLIM, can be used to limit the crystal drive level, if necessary. If the
power dissipated in the selected crystal is higher than the drive level specified for the crystal with RLIM shorted,
then a larger resistor value is mandatory to avoid overdriving the crystal. However, if the power dissipated in the
crystal is less than the drive level with RLIM shorted, then a zero value for RLIM can be used. As a starting point, a
suggested value for RLIM is 1.5 kΩ.
Termination and Use of Clock Drivers
When terminating clock drivers keep in mind these guidelines for optimum phase noise and jitter performance:
• Transmission line theory should be followed for good impedance matching to prevent reflections.
• Clock drivers should be presented with the proper loads.
– HCSL drivers are switched current outputs and require a DC path to ground via 50 Ω termination.
• Receivers should be presented with a signal biased to their specified DC bias level (common mode voltage)
for proper operation. Some receivers have self-biasing inputs that automatically bias to the proper voltage
level; in this case, the signal should normally be AC coupled.
Termination for DC Coupled Differential Operation
50:
For DC coupled operation of an HCSL driver, terminate with 50 Ω to ground near the driver output as shown in
Figure 20. Series resistors, Rs, may be used to limit overshoot due to the fast transient current. Because HCSL
drivers require a DC path to ground, AC coupling is not allowed between the output drivers and the 50 Ω
termination resistors.
CLKoutX
HCSL
Driver
Rs
50:Traces
Rs
HCSL
Receiver
50:
CLKoutX*
Figure 20. HCSL Operation, DC Coupling
Termination for AC Coupled Differential Operation
AC coupling allows for shifting the DC bias level (common mode voltage) when driving different receiver
standards. Since AC coupling prevents the driver from providing a DC bias voltage at the receiver, it is important
to ensure the receiver is biased to its ideal DC level.
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Power Supply and Thermal Considerations
Current Consumption and Power Dissipation Calculations
The current consumption values specified in ELECTRICAL CHARACTERISTICS can be used to calculate the
total power dissipation and IC power dissipation for any device configuration. The total VCC core supply current
(ICC_TOTAL) can be calculated using Equation 5:
ICC_TOTAL = ICC_CORE + ICC_BANKS + ICC_CMOS
where
•
•
•
ICC_CORE is the VCC current for core logic and input blocks and depends on selected input (CLKinX or OSCin).
ICC_HCSL is the VCC current for Banks A & B
ICC_CMOS is the VCC current for the LVCMOS output (or 0 mA if REFout is disabled).
(5)
Since the output supplies (VCCOA, VCCOB, VCCOC) can be powered from 3 independent voltages, the respective
output supply currents (ICCO_BANK_A, ICCO_BANK_B, and ICCO_CMOS) should be calculated separately.
ICCO_BANK for either Bank A or B may be taken as 50% of the corresponding output supply current specified for
two banks (ICCO_HCSL) provided the output loading matches the specified conditions. Otherwise, ICCO_BANK
should be calculated per bank as follows:
ICCO_BANK = IBANK_BIAS + (N * IOUT_LOAD)
where
•
•
•
IBANK_BIAS is the output bank bias current (fixed value).
IOUT_LOAD is the DC load current per loaded output pair.
N is the number of loaded output pairs (N = 0 to 2).
(6)
Table 5 shows the typical IBANK_BIAS values and IOUT_LOAD expressions for HCSL.
Table 5. Typical Output Bank Bias and Load Currents
Current Parameter
HCSL
IBANK_BIAS
2.4 mA
IOUT_LOAD
VOH/RT
Once the current consumption is known for each supply, the total power dissipation (PTOTAL) can be calculated:
PTOTAL = (VCC*ICC_TOTAL) + (VCCOA*ICCO_BANK) + (VCCOB*ICCO_BANK) + (VCCOC*ICCO_CMOS)
(7)
If the device is configured with HCSL outputs, then it is also necessary to calculate the power dissipated in any
termination resistors (PRT_HCSL). The external power dissipation values can be calculated as follows:
PRT_HCSL (per HCSL pair) = VOH2 / RT
(8)
Finally, the IC power dissipation (PDEVICE) can be computed by subtracting the external power dissipation values
from PTOTAL as follows:
PDEVICE = PTOTAL - N*PRT_HCSL
where
•
N is the number of HCSL output pairs with termination resistors to GND.
(9)
Power Dissipation Example: Worst-Case Dissipation
This example shows how to calculate IC power dissipation for a configuration to estimate worst-case power
dissipation. In this case, the maximum supply voltage and supply current values specified in ELECTRICAL
CHARACTERISTICS are used.
• Max VCC = VCCO = 3.465 V. Max ICC and ICCO values.
• CLKin0/CLKin0* input is selected.
• Banks A and B are enabled, and all outputs are terminated with 50 Ω to GND.
• REFout is enabled with 5 pF load.
• TA = 85 °C
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Using the power calculations from the previous section and maximum supply current specifications, we can
compute PTOTAL and PDEVICE.
• From Equation 5: ICC_TOTAL = 10.5 mA + 58.5 mA + 5.5 mA = 74.5 mA
• From ICCO_HCSL max spec: ICCO_BANK = 50% of ICCO_HCSL = 40.75 mA
• From Equation 7: PTOTAL = (3.465 V * 74.5 mA) + (3.465 V * 40.75 mA)+ (3.465 V * 40.75 mA) + (3.465 V *
10 mA) = 575.2 mW
• From Equation 8: PRT_HCSL = (0.92V)2 / 50Ω = 16.9 mW (per output pair)
• From Equation 9: PDEVICE = 575.2 mW - (4 * 16.9 mW) = 510.4 mW
In this worst-case example, the IC device will dissipate about 510.4 mW or 88.7% of the total power (575.2 mW),
while the remaining 11.3% will be dissipated in the termination resistors (64.8 mW for 4 pairs). Based on θJA of
38.1 °C/W, the estimate die junction temperature would be about 19.4 °C above ambient, or 104.4 °C when TA =
85 °C.
Power Supply Bypassing
The Vcc and Vcco power supplies should have a high-frequency bypass capacitor, such as 0.1 uF or 0.01 uF,
placed very close to each supply pin. 1 uF to 10 uF decoupling capacitors should also be placed nearby the
device between the supply and ground planes. All bypass and decoupling capacitors should have short
connections to the supply and ground plane through a short trace or via to minimize series inductance.
Power Supply Ripple Rejection
In practical system applications, power supply noise (ripple) can be generated from switching power supplies,
digital ASICs or FPGAs, etc. While power supply bypassing will help filter out some of this noise, it is important to
understand the effect of power supply ripple on the device performance. When a single-tone sinusoidal signal is
applied to the power supply of a clock distribution device, such as LMK00334, it can produce narrow-band phase
modulation as well as amplitude modulation on the clock output (carrier). In the single-side band phase noise
spectrum, the ripple-induced phase modulation appears as a phase spur level relative to the carrier (measured in
dBc).
For the LMK00334, power supply ripple rejection, or PSRR, was measured as the single-sideband phase spur
level (in dBc) modulated onto the clock output when a ripple signal was injected onto the Vcco supply. The
PSRR test setup is shown in Figure 21.
Ripple
Source
Vcco
Clock
Source
Power
Supplies
Bias-Tee
Vcc
OUT+
IN+
Limiting
Amp
IC
IN-
OUTDUT Board
OUT
Phase Noise
Analyzer
Scope
Measure 100 mVPP
ripple on Vcco at IC
Measure single
sideband phase spur
power in dBc
Figure 21. PSRR Test Setup
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A signal generator was used to inject a sinusoidal signal onto the Vcco supply of the DUT board, and the peakto-peak ripple amplitude was measured at the Vcco pins of the device. A limiting amplifier was used to remove
amplitude modulation on the differential output clock and convert it to a single-ended signal for the phase noise
analyzer. The phase spur level measurements were taken for clock frequencies of 156.25 MHz and 312.5 MHz
under the following power supply ripple conditions:
• Ripple amplitude: 100 mVpp on Vcco = 2.5 V
• Ripple frequencies: 100 kHz, 1 MHz, and 10 MHz
Assuming no amplitude modulation effects and small index modulation, the peak-to-peak deterministic jitter (DJ)
can be calculated using the measured single-sideband phase spur level (PSRR) as follows:
DJ (ps pk-pk) = [(2*10(PSRR / 20)) / (π*fCLK)] * 1012
(10)
The “PSRR vs. Ripple Frequency” plots in TYPICAL CHARACTERISTICS show the ripple-induced phase spur
levels at 156.25 MHz and 312.5 MHz. The LMK00334 exhibits very good and well-behaved PSRR characteristics
across the ripple frequency range. The phase spur levels for HCSL are below -72 dBc at 156.25 MHz and below
-63 dBc at 312.5 MHz. Using Equation 10, these phase spur levels translate to Deterministic Jitter values of 1.02
ps pk-pk at 156.25 MHz and 1.44 ps pk-pk at 312.5 MHz. Testing has shown that the PSRR performance of the
device improves for Vcco = 3.3 V under the same ripple amplitude and frequency conditions.
Thermal Management
Power dissipation in the LMK00334 device can be high enough to require attention to thermal management. For
reliability and performance reasons the die temperature should be limited to a maximum of 125 °C. That is, as an
estimate, TA (ambient temperature) plus device power dissipation times θJA should not exceed 125 °C.
The package of the device has an exposed pad that provides the primary heat removal path as well as excellent
electrical grounding to the printed circuit board. To maximize the removal of heat from the package a thermal
land pattern including multiple vias to a ground plane must be incorporated on the PCB within the footprint of the
package. The exposed pad must be soldered down to ensure adequate heat conduction out of the package.
A recommended land and via pattern is shown in Figure 22. More information on soldering WQFN packages can
be obtained at: http://www.ti.com/packaging.
3.1 mm, min
0.2 mm, typ
1.27 mm,
typ
Figure 22. Recommended Land and Via Pattern
To minimize junction temperature it is recommended that a simple heat sink be built into the PCB (if the ground
plane layer is not exposed). This is done by including a copper area of about 2 square inches on the opposite
side of the PCB from the device. This copper area may be plated or solder coated to prevent corrosion but
should not have conformal coating (if possible), which could provide thermal insulation. The vias shown in
Figure 22 should connect these top and bottom copper layers and to the ground layer. These vias act as “heat
pipes” to carry the thermal energy away from the device side of the board to where it can be more effectively
dissipated.
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PACKAGE OPTION ADDENDUM
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22-Dec-2013
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Op Temp (°C)
Device Marking
(4/5)
LMK00334RTVR
ACTIVE
WQFN
RTV
32
1000
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 85
K00334
LMK00334RTVT
ACTIVE
WQFN
RTV
32
250
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 85
K00334
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
22-Dec-2013
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
23-Dec-2013
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
LMK00334RTVR
WQFN
RTV
32
1000
178.0
12.4
5.3
5.3
1.3
8.0
12.0
Q1
LMK00334RTVT
WQFN
RTV
32
250
178.0
12.4
5.3
5.3
1.3
8.0
12.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
23-Dec-2013
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
LMK00334RTVR
WQFN
RTV
32
1000
213.0
191.0
55.0
LMK00334RTVT
WQFN
RTV
32
250
213.0
191.0
55.0
Pack Materials-Page 2
MECHANICAL DATA
RTV0032A
SQA32A (Rev B)
www.ti.com
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