LMK00105
Ultra-low Jitter LVCMOS Fanout Buffer/Level Translator with Universal
Input
1.0 General Description
The LMK00105 is a high performance, low noise LVCMOS
fanout buffer which can distribute 5 ultra-low jitter clocks from
a differential, single ended, or crystal input. The LMK00105
supports synchronous output enable for glitch free operation.
The ultra low-skew, low-jitter, and high PSRR make this buffer
ideally suited for various networking, telecom, server and
storage area networking, RRU LO reference distribution,
medical and test equipment applications.
The core voltage can be set to 2.5 or 3.3 V, while the output
voltage can be set to 1.5, 1.8, 2.5 or 3.3 V. The LMK00105
can be easily configured through pin programming.
2.0 Target Applications
LO Reference Distribution for RRU Applications
SONET, Ethernet, Fibre Channel Line Cards
Optical Transport Networks
GPON OLT/ONU
Server and Storage Area Networking
Medical Imaging
Portable Test and Measurement
High-end A/V
3.0 Features
5 LVCMOS Outputs, DC to 200 MHz
Universal Input
LVPECL
LVDS
HCSL
SSTL
LVCMOS / LVTTL
Crystal Oscillator Interface
Crystal Input Frequency: 10 to 40 MHz
Output Skew: 6 ps
Additive Phase Jitter
30 fs at 156.25 MHz (12 kHz to 20 MHz)
Low Propagation Delay
Operates with 3.3 or 2.5 V Core Supply Voltage
Adjustable Output Power Supply
1.5 V, 1.8 V, 2.5 V, and 3.3 V For Each Bank
24 pin LLP package (4.0 x 4.0 x 0.8 mm)
4.0 Functional Block Diagram
30180701
TRI-STATE® is a registered trademark of National Semiconductor Corporation.
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.
301807 SNAS579A Copyright © 1999-2012, Texas Instruments Incorporated
5.0 Connection Diagram
24-Pin LLP Package
30180702
6.0 Pin Descriptions
Pin # Pin Name Type Description
DAP DAP - The DAP should be grounded
2, 6 Vddo Power Power Supply for Bank A (CLKout0 and CLKout 1) CLKout pins.
3 CLKout0 Output LVCMOS Output
1,4,7,11,12,
16,19 GND GND Ground
5 CLKout1 Output LVCMOS Output
8,23 Vdd Power Supply for operating core and input buffer
9 OSCin Input Input for Crystal
10 OSCout Output Output for Crystal
13 CLKout2 Output LVCMOS Output
14,18 Vddo Power Power Supply for Bank B (CLKout2 to CLKout 4) CLKout pins
15 CLKout3 Output LVCMOS Output
17 CLKout4 Output LVCMOS Output
20 CLKin* Input Optional complimentary input pin
21 CLKin Input Input Pin
22 SEL Input Input Clock Selection. This pin has an internal pull-down resistor.
(Note 1)
24 OE Input Output Enable. This pin has an internal pull-down resistor. (Note 1)
Note 1: CMOS control input with internal pull-down resistor.
LMK00105
2 Copyright © 1999-2012, Texas Instruments Incorporated
7.0 Absolute Maximum Ratings (Note 2, Note 3)
If Military/Aerospace specified devices are required, please contact the Texas Instruments Sales Office/ Distributors for
availability and specifications.
Parameter Symbol Ratings Units
Core Supply Voltage Vdd -0.3 to 3.6 V
Output Supply Voltage Vddo -0.3 to 3.6 V
Input Voltage VIN -0.3 to Vdd + 0.3 V
Storage Temperature Range TSTG -65 to 150 °C
Lead Temperature (solder 4 s) TL+260 °C
Junction Temperature TJ+125 °C
8.0 Recommended Operating Conditions
Parameter Symbol Min Typ Max Units
Ambient Temperature TA-40 25 85 °C
Core Supply Voltage Vdd 2.375 3.3 3.45 V
Output Supply Voltage (Note 4) Vddo 1.425 3.3 Vdd V
Note 2: "Absolute Maximum Ratings" indicate limits beyond which damage to the device may occur, including inoperability and degradation of device reliability
and/or performance. Functional operation of the device and/or non-degradation at the Absolute Maximum Ratings or other conditions beyond those indicated in
the Recommended Operating Conditions is not implied. The Recommended Operating Conditions indicate conditions at which the device is functional and the
device should not be operated beyond such conditions.
Note 3: This device is a high performance integrated circuit with ESD handling precautions. Handling of this device should only be done at ESD protected work
stations. The device is rated to a HBM-ESD of > 2.5 kV, a MM-ESD of > 250 V, and a CDM-ESD of > 1 kV.
Note 4: Vddo should be less than or equal to Vdd, (Vddo Vdd)
9.0 Package Thermal Resistance
24-Lead LLP
Package Symbols Ratings Units
Thermal resistance from junction to
ambient
on 4-layer Jedec board (Note 5)
θJA 54 ° C/W
Thermal resistance from junction to case
(Note 6)θJC (DAP) 20 ° C/W
Note 5: Specification assumes 5 thermal vias connect to die attach pad to the embedded copper plane on the 4-layer Jedec board. These vias play a key role in
improving the thermal performance of the LLP. For best thermal dissipation it is recommended that the maximum number of vias be used on the board layout.
Note 6: Case is defined as the DAP (die attach pad).
LMK00105
Copyright © 1999-2012, Texas Instruments Incorporated 3
10.0 Electrical Characteristics
(2.375 V Vdd 3.45 V, 1.425 Vddo Vdd, -40 °C TA 85 °C, Differential inputs. Typical values represent most likely
parametric norms at Vdd = Vddo = 3.3 V, TA = 25 °C, at the Recommended Operation Conditions at the time of product charac-
terization and are not guaranteed). Test conditions are: Ftest = 100 MHz, Load = 5 pF in parallel with 50 unless otherwise stated.
Symbol Parameter Test Conditions Min Typ Max Units
Total Device Characteristics
Vdd Core Supply Voltage 2.375 2.5 or
3.3 3.465 V
Vddo Output Supply Voltage 1.425
1.5,1.8,
2.5, or
3.3
Vdd V
IVdd Core Current
No CLKin 16 25
mA
Vddo = 3.3 V, Ftest = 100 MHz 24
Vddo = 2.5 V, Ftest = 100 MHz 20
IVddo[n] Current for Each Output
Vddo = 2.5 V,
OE = High, Ftest = 100 MHz, CL = 10pF 5
mAVddo= 3.3 V,
OE = High, Ftest = 100 MHz, CL = 10pF 7
OE = Low 0.1
IVdd + IVddo
Total Device Current with Loads on
all outputs
OE = High @ 100 MHz 59 mA
OE = Low 16
Power Supply Ripple Rejection (PSRR)
PSRR Ripple Induced
Phase Spur Level
100 kHz, 100 mVpp
Ripple Injected on
Vdd, Vddo = 2.5 V
-44 dBc
Outputs (Note 7)
Skew Output Skew Measured between outputs,
referenced to CLKout0 6 25 ps
tPD
Propagation Delay
CLKin to CLKout
(Note 9)
CL = 5 pF, RL = 50 Ω
Vdd = 3.3 V; Vddo = 3.3 V 1 ns
CL = 5 pF, RL = 50 Ω
Vdd = 2.5 V; Vddo = 1.5 V 1.4 ns
tPD, PP Part-to-part Skew (Note 8, Note 9)
CL = 5 pF, RL = 50 Ω
Vdd = 3.3 V; Vddo = 3.3 V 750 ps
CL = 5 pF, RL = 50 Ω
Vdd = 2.5 V; Vddo = 1.5 V 1.1 ns
fCLKout
Output Frequency
(Note 10) DC 200 MHz
tRise Rise/Fall Time
Vdd = 3.3 V, Vddo = 1.8 V, CL = 10 pF 500
ps
Vdd = 2.5 V, Vddo = 2.5 V, CL = 10 pF 300
Vdd = 3.3 V, Vddo = 3.3 V, CL = 10 pF 200
VCLKoutLow Output Low Voltage 0.1
V
VCLKoutHigh Output High Voltage Vddo-
0.1
RCLKout Output Resistance 50 ohm
tjRMS Additive Jitter
fCLKout = 156.25 MHz,
CMOS input slew rate 2 V/ns
CL = 5 pF, BW = 12 kHz to 20 MHz,
Differential Input Mode Only
30 fs
LMK00105
4 Copyright © 1999-2012, Texas Instruments Incorporated
Symbol Parameter Test Conditions Min Typ Max Units
Digital Inputs (OE, SEL0, SEL1)
VLow Input Low Voltage Vdd = 2.5 V 0.4
V
VHigh Input High Voltage Vdd = 2.5 V 1.3
Vdd = 3.3 V 1.6
IIH High Level Input Current 50 uA
IIL Low Level Input Current -5 5
CLKin/CLKin* Input Clock Specifications, (Note 12, Note 13)
IIH High Level Input Current VCLKin = Vdd 20 uA
IIL
Low Level Input Current
(Note 11)VCLKin = 0 V -20 uA
VIH Input High Voltage Vdd V
VIL Input Low Voltage GND
VCM
Differential Input
Common Mode Input Voltage
(Note 15)
VID = 150 mV 0.5 Vdd-
1.2
V
VID = 350 mV 0.5 Vdd-
1.1
VID = 800 mV 0.5 Vdd-
0.9
VID Differential Input Voltage Swing CLKin driven differentially 0.15 1.5 V
OSCin/OSCout Pins
fOSCin Input Frequency (Note 10) Single-Ended Input, OSCout floating DC 200 MHz
fXTAL Crystal Frequency Input Range
Fundamental Mode Crystal
ESR < 200 Ω ( fXtal 30 MHz )
ESR < 120 Ω ( fXtal > 30 MHz )
(Note 14, Note 10)
10 40 MHz
COSCin Shunt Capacitance 1 pF
VIH Input High Voltage Single-Ended Input, OSCout floating 2.5 V
Note 7: AC Parameters for CMOS are dependent upon output capacitive loading
Note 8: Part-to-part skew is calculated as the difference between the fastest and slowest tPD across multiple devices.
Note 9: Guaranteed by design.
Note 10: Guaranteed by characterization.
Note 11: VIL should not go below -0.3 volts.
Note 12: See Section 12.1 Differential Voltage Measurement Terminology for definition of VOD and VID.
Note 13: Refer to application note AN-912 Common Data Transmission Parameters and their Definitions for more information.
Note 14: The ESR requirements stated are what is necessary in order to ensure that the Oscillator circuitry has no start up issues. However, lower ESR values
for the crystal might be necessary in order to stay below the maximum power dissipation requirements for that crystal.
Note 15: When using differential signals with VCM outside of the acceptable range for the specified VID, the clock must be AC coupled.
LMK00105
Copyright © 1999-2012, Texas Instruments Incorporated 5
11.0 Typical Performance Characteristics
Unless otherwise specified: Vdd = Vddo = 3.3 V, TA = 20 °C, CL = 5 pF, CLKin driven differentially, input slew rate 2 V/ns.
RMS Jitter vs. CLKin Slew Rate @ 100 MHz
0.5 1.0 1.5 2.0 2.5 3.0
0
50
100
150
200
250
300
350
400
450
500
RMS JITTER (fs)
DIFFERENTIAL INPUT SLEW RATE (V/ns)
Fclk-100 MHz
Int. BW=1-20 MHz
-40 C
25 C
85 C
CLKin Source
30180741
Noise Floor vs. CLKin Slew Rate @ 100 MHz
0.5 1.0 1.5 2.0 2.5 3.0
-170
-165
-160
-155
-150
-145
-140
NOISE FLOOR (dBc/Hz)
DIFFERENTIAL INPUT SLEW RATE (V/ns)
Fclk=100 MHz
Foffset=20 MHz
-40 C
25 C
85 C
CLKin Source
30180774
LVCMOS Phase Noise @ 100 MHz
30180742
Note 16: Test conditions: LVCMOS Input, slew rate 2 V/ns, CL = 5 pF in parallel
with 50 , BW = 1 MHz to 20 MHz
LVCMOS Output Swing vs. Frequency
0 200 400 600 800 1000
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
OUTPUT SWING (V)
FREQUENCY (MHz)
Rterm=50 Ω
Vddo=1.5 V
Vddo=1.8 V
Vddo=2.5 V
Vddo=3.3 V
30180775
Iddo per Output vs Frequency
0 50 100 150 200 250
0
5
10
15
CURRENT (mA)
FREQUENCY (MHz)
Cload = 10 pF
Vddo = 1.5 V
Vddo = 1.8 V
Vddo = 2.5 V
Vddo = 3.3 V
30180776
LMK00105
6 Copyright © 1999-2012, Texas Instruments Incorporated
12.0 Measurement Definitions
12.1 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 section
Figure 1 illustrates the two different definitions side-by-side for inputs and Figure 2 illustrates the two different definitions side-by-
side for outputs. The VID and VOD definitions show VA and VB DC levels 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
peak-to-peak voltage of the differential signal can be measured.
VID and VOD are often defined in volts (V) and VSS is often defined as volts peak-to-peak (VPP).
30180712
FIGURE 1. Two Different Definitions for Differential Input Signals
30180713
FIGURE 2. Two Different Definitions for Differential Output Signals
LMK00105
Copyright © 1999-2012, Texas Instruments Incorporated 7
13.0 Functional Description
The LMK00105 is a 5 output LVCMOS clock fanout buffer with low additive jitter that can operate up to 200 MHz. It features a 2:1
input multiplexer with a crystal oscillator input, single supply or dual supply (lower power) operation, and pin-programmable device
configuration. The device is offered in a 24-pin LLP package.
13.1 Vdd and Vddo Power Supplies (Note 17, Note 18)
Separate core and output supplies allow the output buffers to operate at the same supply as the Vdd core supply (3.3 V or 2.5 V)
or from a lower supply voltage (3.3 V, 2.5 V, 1.8 V, or 1.5 V). Compared to single-supply operation, dual supply operation enables
lower power consumption and output-level compatibility.
Bank A (CLKout0 and CLKout1) and Bank B (CLKout2 to CLKout4) may also be operated at different Vddo voltages, provided neither
Vddo voltage exceeds Vdd.
Note 17: Care should be taken to ensure the Vddo voltage does not exceed the Vdd voltage to prevent turning-on the internal ESD protection circuitry.
Note 18: DO NOT DISCONNECT OR GROUND ANY OF THE Vddo PINS as the Vddo pins are internally connected within an output bank.
13.2 CLOCK INPUT
The LMK00105 has one differential input, CLKin/CLKin* and OSCin, that can be driven in different manners that are described in
the following sections.
13.2.1 SELECTION OF CLOCK INPUT
Clock input selection is controlled using the SEL pin as shown in Table 1. Refer to Section 14.1 Driving the Clock Inputs for clock
input requirements. When CLKin is selected, the crystal circuit is powered down. When OSCin is selected, the crystal oscillator will
start-up and its clock will be distributed to all outputs.
TABLE 1. Input Selection
SEL Input
0 CLKin, CLKin*
1OSCin
(Crystal Mode)
13.2.1.1 CLKin/CLKin* Pins
The LMK00105 has a differential input (CKLin/CLKin*) which can be driven single-ended or differentially. It can accept AC or DC
coupled 3.3V/2.5V LVPECL, LVDS, or other differential and single ended signals that meet the input requirements in Section 10.0
Electrical Characteristics and (Note 15). Refer to Section 14.1 Driving the Clock Inputs for more details on driving the LMK00105
inputs.
In the event that a Crystal mode is not selected and the CLKin pins do not have an AC signal applied to them, Table 2 will be the
state of the outputs.
TABLE 2. CLKin Input vs. Output States
CLKin Output State
Open Logic Low
Logic Low Logic Low
Logic High Logic High
13.2.1.2 OSCin/OSCout Pins
The LMK00105 has a crystal oscillator which will be powered up when OSCin is selected. Alternatively, OSCin may be driven by
a single ended clock, up to 200 MHz, instead of a crystal. Refer to Section 14.2 Crystal Interface for more information.
If Crystal mode is selected and the pins do not have an AC signal applied to them, Table 3 will be the state of the outputs. If Crystal
mode is selected an open state is not allowed on OSCin, as the outputs may oscillate due to the crystal oscillator circuitry.
TABLE 3. OSCin Input vs. Output States
OSCin Output State
Open Not Allowed
Logic Low Logic High
Logic High Logic Low
LMK00105
8 Copyright © 1999-2012, Texas Instruments Incorporated
13.3 CLOCK OUTPUTS
The LMK00105 has 5 LVCMOS outputs.
13.3.1 Output Enable Pin
When the output enable pin is held High, the outputs are enabled. When it is held Low, the outputs are held in a Low state as shown
in Table 4.
TABLE 4. Output Enable Pin States
OE Outputs
Low Disabled (Hi-Z)
High Enabled
The OE pin is synchronized to the input clock to ensure that there are no runt pulses. When OE is changed from Low to High, the
outputs will initially have an impedance of about 400 Ω to ground until the second falling edge of the input clock and starting with
the second falling edge of the input clock, the outputs will buffer the input. If the OE pin is taken from Low to High when there is no
input clock present, the outputs will either go high or low and stay a that state; they will not oscillate. When the OE pin is taken from
High to Low the outputs will be Low after the second falling edge of the clock input and then will go to a Disabled (Hi-Z) state starting
after the next rising edge.
13.3.2 Using Less than Five Outputs
Although the LMK00105 has 5 outputs, not all applications will require all of these. In this case, the unused outputs should be left
floating with a minimum copper length (Note 19) to minimize capacitance. In this way, this output will consume minimal output
current because it has no load.
Note 19: For best soldering practices, the minimum trace length 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.
LMK00105
Copyright © 1999-2012, Texas Instruments Incorporated 9
14.0 Application Information
14.1 Driving the Clock Inputs
The LMK00105 has a differential input (CLKin/CLKin*) that can accept AC or DC coupled 3.3V/2.5V LVPECL, LVDS, and other
differential and single ended signals that meet the input requirements specified in Section 10.0 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. AC coupling may also be employed to shift the input signal to within the VCM range.
To achieve the best possible phase noise and jitter performance, it is recommended that the input to have a high slew rate of 2 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
input signal is recommended over single-ended because it typically provides higher slew rate and common-mode noise rejection.
While it is recommended to drive CLKin with a differential signal input, it is possible to drive them with a single ended clock. 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. The input can be AC coupled as shown in Figure 3 which is the preferred configuration, or Figure 4,
or Figure 5 depending upon the application. In these cases, the output impedance of the CMOS driver plus RS should be matched
as closely as possible to the 50 termination resistor for best performance.
30180738
FIGURE 3. Preferred Configuration: Single-Ended LVCMOS Input, AC Coupling
30180743
FIGURE 4. Single-Ended LVCMOS Input, AC Coupling
Near End Termination
30180744
FIGURE 5. Single-Ended LVCMOS Input, AC Coupling,
Far End Temination
A single ended clock may also be DC coupled to CLKin as shown in Figure 6. If the DC coupled input swing has a common mode
level near the devices internal bias of 1.4 V, then only a 0.1 µF bypass cap is required on CLKin*. Otherwise, if the input swing is
not optimally centered near the internal bias voltage, then CLKin* should be externally biased to the midpoint voltage of the input
swing. This can be achieved using external biasing resistors, RB1 and RB2, or another low-noise voltage reference. The external
bias voltage should be within the specified input common voltage (VCM) range. This will ensure the input swing crosses the
threshold voltage at a point where the input slew rate is the highest.
LMK00105
10 Copyright © 1999-2012, Texas Instruments Incorporated
30180739
FIGURE 6. Single-Ended LVCMOS Input, DC Coupling with Common Mode Biasing
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 7. Configurations similar to Figure 4 or Figure 5 could also be used as long as the OSCout pin is left floating. In these cases,
the output impedance of the CMOS driver plus RS should be matched as closely as possible to the 50 termination resistor for
best performance. The input clock should be AC coupled to the OSCin pin, which has an internally generated input bias voltage,
and the OSCout pin should be left floating. While OSCin provides an alternative input to multiplex an external clock, it is recom-
mended to use either differential input (CLKin) since it offers higher operating frequency, better common mode, improved power
supply noise rejection, and greater performance over supply voltage and temperature variations.
30180703
FIGURE 7. Driving OSCin with a Single-Ended
14.2 Crystal Interface
The LMK00105 has an integrated crystal oscillator circuit that supports a fundamental mode, AT-cut crystal. The crystal interface
is shown in Figure 8.
30180704
FIGURE 8. Crystal Interface
The load capacitance (CL) is specific to the crystal, but usually on the order of 18 to 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 to 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 C1only:
CL = C12 / (2 * C1) + CIN + CSTRAY (2)
Finally, solve for C1:
C1 = (CL - CIN - CSTRAY) * 2 (3)
Section 10.0 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
LMK00105
Copyright © 1999-2012, Texas Instruments Incorporated 11
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.
The power dissipated in the crystal, PXTAL, can be computed by:
PXTAL = IRMS2 * RESR * (1 + C0 / CL)2(4)
Where:
IRMS is the RMS current through the crystal.
RESR is the maximum equivalent series resistance specified for the crystal.
CL is the load capacitance specified for the crystal.
C0 is the mininimum shunt capacitance specified for the crystal.
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 8, 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.
14.3 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 LMK00105, it can produce narrow-band phase modulation as well as amplitude modulation on the clock output
(carrier). In the singleside band phase noise spectrum, the ripple-induced phase modulation appears as a phase spur level relative
to the carrier (measured in dBc).
For the LMK00105, power supply ripple rejection (PSRR), was measured as the single-sideband phase spur level (in dBc) modu-
lated onto the clock output when a ripple signal was injected onto the Vddo supply. The PSRR test setup is shown in Figure 9.
30180740
FIGURE 9. PSRR Test Setup
A signal generator was used to inject a sinusoidal signal onto the Vddo supply of the DUT board, and the peak-to-peak ripple
amplitude was measured at the Vddo 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 100 MHz under the following power supply ripple conditions:
Ripple amplitude: 100 mVpp on Vddo = 2.5 V
Ripple frequency: 100 kHz
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 (5)
14.4 Power Supply Bypassing
The Vdd and Vddo power supplies should have a high frequency bypass capacitor, such as 100 pF, placed very close to each supply
pin. Placing the bypass capacitors on the same layer as the LMK00105 improves input sensitivity and performance. 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.
14.5 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 consumption times θJA should not exceed 125 °C.
LMK00105
12 Copyright © 1999-2012, Texas Instruments Incorporated
The package of the device has an exposed pad that provides the primary heat removal path as well as excellent electrical grounding
to a 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 10. More information on soldering LLP packages and gerber footprints
can be obtained: http://www.national.com/en/packaging/index.html.
A recommended footprint including recommended solder mask and solder paste layers can be found at: http://www.national.com/
en/packagingl/gerber.html for the SQA24A package.
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 10 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.
30180773
FIGURE 10. Recommended Land and Via Pattern
LMK00105
Copyright © 1999-2012, Texas Instruments Incorporated 13
15.0 Physical Dimensions inches (millimeters) unless otherwise noted
Leadless Leadframe Package (Bottom View)
24 Pin LLP Package
16.0 Ordering Information
Order Number Package Marking Packaging
LMK00105SQX
K00105
4500 Unit Tape and Reel
LMK00105SQ 1000 Unit Tape and Reel
LMK00105SQE 250 Unit Tape and Reel
LMK00105
14 Copyright © 1999-2012, Texas Instruments Incorporated
Notes
LMK00105
Copyright © 1999-2012, Texas Instruments Incorporated 15
Notes
Copyright © 1999-2012, Texas Instruments
Incorporated
IMPORTANT NOTICE
Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements,
and other changes to its products and services at any time and to discontinue any product or service without notice. Customers should
obtain the latest relevant information before placing orders and should verify that such information is current and complete. All products are
sold subject to TIs terms and conditions of sale supplied at the time of order acknowledgment.
TI warrants performance of its hardware products to the specifications applicable at the time of sale in accordance with TIs standard
warranty. Testing and other quality control techniques are used to the extent TI deems necessary to support this warranty. Except where
mandated by government requirements, testing of all parameters of each product is not necessarily performed.
TI assumes no liability for applications assistance or customer product design. Customers are responsible for their products and
applications using TI components. To minimize the risks associated with customer products and applications, customers should provide
adequate design and operating safeguards.
TI does not warrant or represent that any license, either express or implied, is granted under any TI patent right, copyright, mask work right,
or other TI intellectual property right relating to any combination, machine, or process in which TI products or services are used. Information
published by TI regarding third-party products or services does not constitute a license from TI to use such products or services or a
warranty or endorsement thereof. Use of such information may require a license from a third party under the patents or other intellectual
property of the third party, or a license from TI under the patents or other intellectual property of TI.
Reproduction of TI information in TI data books or data sheets is permissible only if reproduction is without alteration and is accompanied
by all associated warranties, conditions, limitations, and notices. Reproduction of this information with alteration is an unfair and deceptive
business practice. TI is not responsible or liable for such altered documentation. Information of third parties may be subject to additional
restrictions.
Resale of TI products or services with statements different from or beyond the parameters stated by TI for that product or service voids all
express and any implied warranties for the associated TI product or service and is an unfair and deceptive business practice. TI is not
responsible or liable for any such statements.
TI products are not authorized for use in safety-critical applications (such as life support) where a failure of the TI product would reasonably
be expected to cause severe personal injury or death, unless officers of the parties have executed an agreement specifically governing
such use. Buyers represent that they have all necessary expertise in the safety and regulatory ramifications of their applications, and
acknowledge and agree that they are solely responsible for all legal, regulatory and safety-related requirements concerning their products
and any use of TI products in such safety-critical applications, notwithstanding any applications-related information or support that may be
provided by TI. Further, Buyers must fully indemnify TI and its representatives against any damages arising out of the use of TI products in
such safety-critical applications.
TI products are neither designed nor intended for use in military/aerospace applications or environments unless the TI products are
specifically designated by TI as military-grade or "enhanced plastic."Only products designated by TI as military-grade meet military
specifications. Buyers acknowledge and agree that any such use of TI products which TI has not designated as military-grade is solely at
the Buyer's risk, and that they are solely responsible for compliance with all legal and regulatory requirements in connection with such use.
TI products are neither designed nor intended for use in automotive applications or environments unless the specific TI products are
designated by TI as compliant with ISO/TS 16949 requirements. Buyers acknowledge and agree that, if they use any non-designated
products in automotive applications, TI will not be responsible for any failure to meet such requirements.
Following are URLs where you can obtain information on other Texas Instruments products and application solutions:
Products Applications
Audio www.ti.com/audio Automotive and Transportation www.ti.com/automotive
Amplifiers amplifier.ti.com Communications and Telecom www.ti.com/communications
Data Converters dataconverter.ti.com Computers and Peripherals www.ti.com/computers
DLP®Products www.dlp.com Consumer Electronics www.ti.com/consumer-apps
DSP dsp.ti.com Energy and Lighting www.ti.com/energy
Clocks and Timers www.ti.com/clocks Industrial www.ti.com/industrial
Interface interface.ti.com Medical www.ti.com/medical
Logic logic.ti.com Security www.ti.com/security
Power Mgmt power.ti.com Space, Avionics and Defense www.ti.com/space-avionics-defense
Microcontrollers microcontroller.ti.com Video and Imaging www.ti.com/video
RFID www.ti-rfid.com
OMAP Mobile Processors www.ti.com/omap
Wireless Connectivity www.ti.com/wirelessconnectivity
TI E2E Community Home Page e2e.ti.com
Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265
Copyright ©2012, Texas Instruments Incorporated