NSC LMX2313USLDX

LMX2310U/LMX2311U/LMX2312U/LMX2313U
PLLatinum™ Ultra Low Power Frequency Synthesizer for
RF Personal Communications
LMX2310U 2.5 GHz
LMX2311U 2.0 GHz
LMX2312U 1.2 GHz
LMX2313U 600 MHz
General Description
Features
The LMX2310/1/2/3U are high performance frequency synthesizers. The LMX2310/1/2U use a selectable, dual modulus 32/33 and 16/17 prescaler. The LMX2313U uses a selectable, dual modulus 16/17 and 8/9 prescaler. The device,
when combined with a high quality reference oscillator and a
voltage controlled oscillator, generates very stable, low noise
local oscillator signals for up and down conversion in wireless communication devices.
Serial data is transferred into LMX2310/1/2/3U via a threewire interface (Data, Enable, Clock) that can be directly
interfaced with low voltage baseband processors. Supply
voltage can range from 2.7V to 5.5V. LMX2310U features
very low current consumption, typically 2.3 mA at 3.0V.
The LMX2310/1/2/3U are manufactured using National’s
0.5µ ABiC V silicon BiCMOS process and is available in
20-pin CSP packages.
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RF operation up to 2.5 GHz
2.7V to 5.5V operation
Ultra Low Current Consumption
Low prescaler values
LMX2310/1/2U 32/33 or 16/17
LMX2313U 16/17 or 8/9
Excellent Phase Noise
Internal balanced, low leakage charge pump
Selectable Charge Pump Current Levels
Selectable Fastlock mode with Time-Out Counter
Low Voltage MICROWIRE interface (1.72V to VCC)
Digital and Analog Lock Detect
Small 20-pad Thin Chip Scale Package
Applications
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Cellular DCS, PCS, WCDMA telephone systems
Wireless Local Area Networks (WLAN)
Global Positioning Systems (GPS)
Other wireless communications systems
Functional Block Diagram
20043822
PLLatinum™ is a trademark of National Semiconductor Corporation.
© 2003 National Semiconductor Corporation
DS200438
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LMX2310U/LMX2311U/LMX2312U/LMX2313U PLLatinum Ultra Low Power Frequency Synthesizer
for RF Personal Communications
December 2003
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Connection Diagram
20043823
20-Pin Thin Chip Scale Package
NS Package Number SLD20A
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2
Pin Number
Pin Name
I/O
Description
1
NC
— No Connect.
2
CPo
O Charge Pump output. For connection to a
loop filter for driving the voltage control
input of an external VCO.
3
GND
— Analog ground.
4
FIN
I
RF prescaler input. Small signal input
from the VCO.
5
FINB
I
RF prescaler complementary input. For
single ended operation, this pin should be
AC grounded. The LMX2310/1/2/3U can
be driven differentially when a bypass
capacitor is omitted.
6
OSCIN
I
Oscillator input. An input to a CMOS low
noise inverting buffer. The input can be
driven from an external CMOS or TTL
logic gate.
7
NC
— No Connect.
8
OSCOUT
O
Oscillator output. The OSCIN low noise
buffer drives an independent oscillator
buffer. Its output is connected to the
OSCOUT pin. It can be used as a buffer to
provide the reference oscillator frequency
to other circuitry or as a crystal oscillator.
9
FoLD
O
Multi-function CMOS output pin that
provides multiplexed access to digital lock
detect, open drain analog lock detect, as
well as the outputs of the R and N
counters. The FoLD pin is internally
referenced to VµC.
10
Clock
I
High impedance CMOS Clock input. Data
for the counters is clocked in on the rising
edge, into the 22-bit shift register. The
Clock is internally referenced to VµC.
3
I/O Circuit Configuration
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Pin Descriptions
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Pin Descriptions
Pin Number
(Continued)
Pin Name
I/O
11
NC
— No Connect.
12
Data
I
High impedance CMOS Data input. Serial
Data is entered MSB first. The last two
bits are the address for the target
registers. The Data is internally referenced
to VµC.
13
LE
I
High impedance CMOS LE input. When
Latch Enable goes HIGH, data stored in
the 22-bit shift register is loaded into one
the 3 control registers, based on the
address field. The Latch Enable is
internally referenced to VµC.
14
GND
15
CE
16
VµC
— Power supply for MICROWIRE™ circuitry.
Must be ≤ VCC. Typically connected to
same supply level as microprocessor or
baseband controller to enable
programming at low voltages.
17
NC
— No Connect.
18
VCC
— Power supply voltage input. Input may
range from 2.7V to 5.5V. Bypass
capacitors should be placed as close as
possible to this pin and be connected
directly to the ground plane.
19
FL
O Fastlock mode output. In Fastlock mode
this pin is at logic low. When not in
Fastlock mode, this pin is in TRI-STATE
mode. This pin can also be forced to
TRI-STATE, forced low or forced high by
the programming of the first two-bits of the
Timeout Counter.
20
VP
— Power supply for charge pump. Must be ≥
VCC.
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Description
— Digital ground.
I
High impedance CMOS Chip Enable
input. Provides logical power-down control
of the device. Pull-up to VµC if unused.
The Chip Enable is internally referenced
to VµC.
4
I/O Circuit Configuration
Lead Temp. (solder 4 sec.), (TL)
(Notes 1,
+260˚C
2)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Recommended Operating
Conditions (Note 1)
Power Supply Voltage,
(VCC, VP, VµC)
Power Supply Voltage
Min Max Unit
−0.3V to +6.5V
(VCC)
Voltage on any pin with GND=0V
2.7
5.5
V
V
CPo, FL, FIN, OSCIN, OSCOUT (Vi) −0.3V to VCC + 0.3V
(VP)
VCC 5.5
Data, Clock, LE, CE, FoLD (Vi)
(VµC)
1.72 VCC
V
−40 +85
˚C
−0.3V to VµC + 0.3V
Storage Temperature Range, (TS)
Operating Temperature, (TA)
−65˚C to +150˚C
Electrical Characteristics
VCC = VP = VµC = 3.0V, −40˚C < TA < +85˚C unless specified otherwise.
Symbol
Parameter
Conditions (Note 3)
Min
Typ
Max
Units
ICC
LMX2310U
lCC
Power Supply
Current
LMX2311U
LMX2312U
LMX2313U
ICC-PWDN
Power-Down Current
(Note 4)
2.3
3.0
mA
3.4
mA
2.0
2.7
mA
3.2
mA
1.4
2.0
mA
2.4
mA
1.0
1.3
mA
1.6
mA
10
µA
VCC = 5.5V (Note 4)
(Note 4)
VCC = 5.5V (Note 4)
(Note 4)
VCC = 5.5V (Note 4)
(Note 4)
VCC = 5.5V (Note 4)
Clock, Data and LE = GND
CE = GND
1
RF PRESCALER
FIN
PFIN
Operating
Frequency
LMX2310U
0.5
2.5
GHz
LMX2311U
0.5
2.0
GHz
LMX2312U
0.2
1.2
GHz
LMX2313U
45
600
MHz
2.7 ≤ VCC ≤3.0V (Note 5)
−15
0
dBm
3.0V < VCC ≤ 5.5V (Note 5)
−10
0
dBm
10
MHz
2
50
MHz
0.5
VCC
VP−P
Input Sensitivity, RF
Prescaler
PHASE DETECTOR
Fφ
Phase Detector Frequency
REFERENCE OSCILLATOR
FOSC
Operating Frequency,
Reference Oscillator Input
VOSCIN
Input Sensitivity,
Reference Oscillator Input
(Note 6)
IIH
OSCIN Input Current
VIH = VCC = 5.5V
IIL
OSCIN Input Current
VIL = 0, VCC = 5.5V
100
VOSCOUT
OSCOUT Bias Level
OSCIN Open
1.5
V
DOSCOUT
OSCOUT Duty Cycle
OSCIN = 20 MHz, 0.5 VP-P,
OSCIN Duty Cycle = 50%
50
%
VOSCOUT
OSCOUT Level
OSCIN = 20 MHz, 0.5 VP-P ,
OSCOUT Load = 10 pF || 10 k
Ohm
2.6
VP-P
VOH
OSCOUT Output Voltage
IOH = -500 µA
2.8
V
−100
2.6
µA
µA
VOL
OSCOUT Output Voltage
IOL = 500 µA
0.2
IOH
OSCOUT Output Current
VOH = 2.25 V
-1.1
mA
IOL
OSCOUT Output Current
VOL = 0.75 V
1.1
mA
5
0.4
V
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Absolute Maximum Ratings
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Electrical Characteristics
(Continued)
VCC = VP = VµC = 3.0V, −40˚C < TA < +85˚C unless specified otherwise.
Symbol
Parameter
Conditions (Note 3)
Min
Typ
Max
Units
CHARGE PUMP
ICPo-source
VCPo = Vp/2, ICPo_4X = 0
0.8
1.0
1.2
mA
ICPo-sink
VCPo = Vp/2, ICPo_4X = 0
−0.8
−1.0
−1.2
mA
ICPo-source
Charge Pump Output
Current (Note 7)
ICPo-sink
VCPo = Vp/2, ICPo_4X = 1
3.2
4.0
4.8
mA
VCPo = Vp/2, ICPo_4X = 1
−3.2
−4.0
−4.8
mA
2.5
nA
ICPo-tri
Charge Pump TRI-STATE
Current
0.5V ≤ VCPo ≤ VP − 0.5V
ICPo-sink vs.
ICPo-source
CP Sink vs. Source
Mismatch
VCPo = Vp/2
TA = 25˚C
(Note 8)
3
10
%
ICPo vs VCPo CP Current vs. Voltage
0.5V ≤ VCPo ≤ VP − 0.5V
TA = 25˚C (Note 8)
8
15
%
ICPo vs TA
VCPo = Vp/2V (Note 7)
CP Current vs.
Temperature
−2.5
8
%
DIGITAL INTERFACE (Data, Clock, LE, CE)
VIH
High-level Input Voltage
VµC = 1.72V to 5.5V
VIL
Low-level Input Voltage
VµC = 1.72V to 5.5V
IIH
High-level Input Current
VIH = VµC= 5.5V
IIL
Low-level Input Current
VIL = 0V, VµC = 5.5V
VOH
High-level Output Voltage
(Pin 7–FoLD)
IOH = 500 µA
High-level Output Voltage
(Pin 15–FL)
IOH = −500 µA
Low-level Output Voltage
IOL = 1.0 mA (Note 9)
VOL
0.8 VµC
V
0.2 VµC
V
−1.0
1.0
µA
−1.0
1.0
µA
VµC − 0.4
V
VCC − 0.4
V
0.1
0.4
V
MICROWIRE TIMING (Data, Clock, LE, CE)
tCS
Data to Clock Set Up Time (Note 10)
50
ns
tCH
Data to Clock Hold Time
(Note 10)
20
ns
tCWH
Clock Pulse Width High
(Note 10)
50
ns
tCWL
Clock Pulse Width Low
(Note 10)
50
ns
tES
Clock to Load Enable Set
Up Time
(Note 10)
50
ns
tEW
Load Enable Pulse Width
(Note 10)
50
ns
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6
(Continued)
VCC = VP = VµC = 3.0V, −40˚C < TA < +85˚C unless specified otherwise.
Symbol
Parameter
Conditions (Note 3)
Min
Typ
Max
Units
PHASE NOISE CHARACTERISTICS
LN(f)
L(f)
Normalized Single
Side-Band Phase Noise
Single Side-Band Phase
Noise
Fφ = 200 kHz
FOSC = 10 MHz
VOSC = 1.0 VPP
ICPO = 4 mA
TA = 25˚C
(Note 11)
−159
dBc/Hz
LMX2310U
FIN = 2450 MHz
Fφ = 200 kHz
FOSC = 10 MHz
VOSC = 1.0 VPP
ICPO = 4 mA
TA = 25˚C
(Note 12)
−78
dBc/Hz
LMX2311U
FIN = 1960 MHz
Fφ = 200 kHz
FOSC = 10 MHz
VOSC = 1.0 VPP
ICPO = 4 mA
TA = 25˚C
(Note 12)
−80
dBc/Hz
LMX2312U
FIN = 902 MHz
Fφ = 200 kHz
FOSC = 10 MHz
VOSC = 1.0 VPP
ICPO = 4 mA
TA = 25˚C
(Note 12)
−85
dBc/Hz
LMX2313U
FIN = 450 MHz
Fφ = 50 kHz
FOSC = 10 MHz
VOSC = 1.0 VPP
ICPO = 4 mA
TA = 25˚C
(Note 12)
−85
dBc/Hz
Note 1: 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 guarantee specific performance limits. For guaranteed specifications and conditions, see the Electrical Characteristics. The
guaranteed specifications apply only for the conditions listed.
Note 2: This device is a high performance RF integrated circuit with an ESD rating < 2 kV. Handling and assembly of this device should only be done at ESD free
workstations.
Note 3: Typical Conditions are at a TA of 25˚C.
Note 4: Icc current is measured with Clock, Data and LE pins connected to GND. OSCin and Fin pins are connected to Vcc. PWDN bit is program to 0. Icc current
is the current into Vcc pin.
Note 5: See FIN Sensitivity Test Setup.
Note 6: See OSCIN Sensitivity Test Setup.
Note 7: Charge Pump Magnitude is controlled by CPo_4X bit [R18].
Note 8: See Charge Pump Measurement Definition for detail on how these measurements are made.
Note 9: Analog Lock Detect open drain output pin only can be pulled up to Vext that will not exceed 6.5V.
Note 10: See Serial Input Data Timing.
Note 11: Normalized Single-Side Band Phase Noise is defined as: LN(f) = L(f) − 20 log (FIN/ Fφ), where L(f) is defined as the Single Side-Band Phase Noise.
7
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Electrical Characteristics
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Note 12: Phase Noise is measured using a reference evaluation board with a loop bandwidth of approximately 12 kHz. The phase noise specification is the
composite average of 3 measurements made at frequency offsets of 2.0 kHz, 2.5 kHz and 3.0 kHz.
Typical Performance Characteristics
Icc vs Vcc LMX2310U
Icc vs Vcc LMX2311U
20043838
20043839
Icc vs Vcc LMX2312U
Icc vs Vcc LMX2313U
20043840
20043841
CPOTRI-STATE vs CPO Voltage
20043843
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8
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX231xU Charge Pump Sweeps
20043842
9
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
Charge Pump Current Variation (See formula under
Charge Pump Current Specification Definitions)
Sink Vs Source Mismatch (See formula under Charge
Pump Current Specification Definitions)
20043866
20043867
LMX2310U Fin Sensitivity vs Frequency at 3.0V
20043846
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10
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX2310U Fin Sensitivity vs Frequency at 5.5V
20043847
LMX2311U Fin Sensitivity vs Frequency at 3.0V
20043848
11
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX2311U Fin Sensitivity vs Frequency at 5.5V
20043849
LMX2312U Fin Sensitivity vs Frequency at 3.0V
20043850
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12
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX2312U Fin Sensitivity vs Frequency at 5.5V
20043851
LMX2313U Fin Sensitivity vs Frequency at 3.0V
20043852
13
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX2313U Fin Sensitivity vs Frequency at 5.5V
20043853
LMX231XU OSCin Sensitivity vs Frequency at 3.0V
20043854
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14
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX231XU OSCin Sensitivity vs Frequency at 5.5V
20043855
LMX231xU OSCin Input Impedance vs Frequency
20043858
15
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX231xUSLD OSCIN IMPEDANCE
VCC = 3.0V (TA = 25˚C)
OSCIN BUFFER
NORMAL OPERATION
VCC = 5.5V (TA = 25˚C)
OSCI N BUFFER
POWERED-DOWN MODE
OSCIN BUFFER
NORMAL OPERATION
OSCIN BUFFER
POWERED-DOWN MODE
ImagImagImagImagReal
Real
Real
Real
FOSC
inary |ZOSCIN|
inary |ZOSCIN|
inary |ZOSCIN|
inary |ZOSCIN|
ZOSCIN
ZOSCIN
ZOSCIN
ZOSCIN
(MHz)
(Ω)
(Ω)
(Ω)
(Ω)
ZOSCIN
ZOSCIN
ZOSCIN
ZOSCIN
(Ω)
(Ω)
(Ω)
(Ω)
(Ω)
(Ω)
(Ω)
(Ω)
2
12900
−1500
13000
9000
−33000
34200
10000
−7400
12400
12000
−35000
37000
4
5200
−10900
12100
2000
−20000
20100
5500
−7800
9500
12200
−21000
24300
7
2400
−7500
7900
1100
−13000
13000
2700
−5700
6300
1300
−13000
13100
10
1350
−5400
5600
410
−9500
9500
1600
−4500
4800
800
−9100
9100
13
920
−4300
4400
350
−7000
7000
1000
−3500
3600
300
−7800
7800
16
820
−3600
3700
450
−5900
5900
800
−3900
4000
400
−6000
6000
19
630
−3100
3200
220
−5000
5000
630
−2500
2600
310
−5100
5100
22
570
−2600
2700
200
−4300
4300
540
−2100
2200
280
−4400
4400
25
420
−2100
2100
150
−3800
3800
450
−1900
2000
180
−3900
3900
28
440
−2000
2000
140
−3400
3400
400
−1700
1700
140
−3500
3500
31
390
−1900
1900
140
−3000
3000
350
−1500
1500
120
−3100
3100
34
360
−1800
1800
80
−2700
2700
330
−1400
1440
110
−2900
2900
37
340
−1700
1700
100
−2500
2500
310
−1300
1340
100
−2600
2600
40
330
−1500
1500
100
−2400
2400
300
−1200
1240
120
−2400
2400
43
300
−1400
1400
95
−2200
2200
280
−1100
1140
100
−2300
2300
46
290
−1400
1400
80
−2100
2100
270
−1000
1040
90
−2100
2100
49
280
−1300
1300
70
−1900
1900
260
−1000
1030
80
−2000
2000
50
280
−1300
1300
70
−1900
1900
260
−990
1020
100
−2000
2000
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16
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX231xU Fin Input Impedance vs Frequency
VCC =3.0V, TA = 25˚C
20043856
LMX231xU Fin Input Impedance vs Frequency
VCC =5.5V, TA = 25˚C
20043857
17
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Typical Performance Characteristics
(Continued)
LMX231xUSLD FIN IMPEDANCE
VCC = 3.0V (TA = 25˚C)
FIN
POWERED-UP
VCC = 5.5V (TA = 25˚C)
FIN
POWERED-DOWN
FIN
POWERED-UP
FIN
POWERED-DOWN
FIN
(MHz)
Real
ZFIN
(Ω)
Imaginary
ZFIN
(Ω)
|ZFIN|
(Ω)
Real
ZFIN
(Ω)
Imaginary
ZFIN
(Ω)
|ZFIN|
(Ω)
Real
ZFIN
(Ω)
Imaginary
ZFIN
(Ω)
|ZFIN|
(Ω)
Real
ZFIN
(Ω)
Imaginary
ZFIN
(Ω)
|ZFIN|
(Ω)
100
452
−325
557
440
−337
554
460
−325
563
444
−333
555
200
305
−278
413
300
−276
408
313
−277
418
312
−275
416
300
225
−243
331
225
−242
330
235
−244
339
237
−244
340
400
180
−219
283
179
−217
281
190
−221
291
189
−221
291
500
147
−197
246
145
−195
243
155
−200
253
155
−200
253
600
120
−175
212
118
−173
209
127
−179
219
126
−179
219
700
102
−158
188
100
−156
185
108
−162
195
107
−161
193
800
88
−141
166
86
−139
163
94
−146
174
91
−143
169
900
78
−126
148
75
−123
144
83
−131
155
81
−129
152
1000
73
−117
138
72
−113
134
78
−118
141
75
−116
138
1100
64
−109
126
63
−106
123
69
−112
132
68
−111
130
1200
57
−98
113
55
−95
110
61
−102
119
59
−100
116
1300
52
−90
104
52
−86
100
55
−95
110
55
−91
106
1400
46
−84
96
46
−83
95
49
−88
101
50
−87
100
1500
41
−75
85
40
−73
83
44
−79
90
42
−78
89
1600
39
−69
79
37
−66
76
41
−73
84
40
−70
81
1700
35
−61
70
34
−59
68
37
−65
75
36
−63
73
1800
34
−55
65
33
−52
62
35
−58
68
34
−56
66
1900
35
−50
61
35
−47
59
35
−52
63
35
−50
61
2000
37
−50
62
37
−48
61
38
−50
63
38
−48
61
2100
34
−52
62
33
−51
61
36
−52
63
34
−51
61
2200
29
−50
58
27
−48
55
32
−51
60
30
−50
58
2300
25
−48
54
23
−45
51
27
−50
57
25
−48
54
2400
20
−44
48
19
−42
46
23
−47
52
21
−44
49
2500
18
−41
45
16
−38
41
20
−43
47
18
−41
45
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18
LMX2310U/LMX2311U/LMX2312U/LMX2313U
Charge Pump Measurement Definitions
20043837
I1 = CPo sink current at VCPo = VP − ∆V
I2 = CPo sink current at VCPo = VP/2
I3 = CPo sink current at VCPo = ∆V
I4 = CPo source current at VCPo = VP − ∆V
I5 = CPo source current at VCPo = VP/2
I6 = CPo source current at VCPo = ∆V
∆V = 0.5V
Charge Pump Output Current Magnitude Variation Vs Charge Pump Output Voltage
20043863
Charge Pump Output Current Sink Vs Charge Pump Output Current Source Mismatch
20043864
Charge Pump Output Current Magnitude Variation Vs Temperature
20043865
19
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
Serial Data Input Timing
20043810
Notes:
1. Data shifted into register on Clock rising edge.
2. Data is shifted in MSB first.
FIN Sensitivity Test Setup
20043830
Notes:
1. LMX2310/1/2U Test Conditions: NA_CNTR = 16, NB_CNTR = 312, P = 1, FoLD2 = 1, FoLD1 = 1, FoLD0 = 0, PWDN = 0.
2. LMX2313U Test Conditions: NA_CNTR = 0, NB_CNTR = 625, P = 1, FoLD2 = 1, FoLD1 = 1, FoLD0 = 0, PWDN = 0.
3. Sensitivity limit is reached when the frequency error of the divided RF input is greater than or equal to 1 Hz.
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20
LMX2310U/LMX2311U/LMX2312U/LMX2313U
OSCIN Sensitivity Test Setup
20043831
Notes:
1. Test Conditions: R_CNTR = 1000, FoLD2 = 1, FoLD1 = 0, FoLD0 = 1, PWDN = 0.
2. Sensitivity limit is reached when the frequency error of the divided RF input is greater than or equal to 1 Hz.
21
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
dividing the VCO frequency down by way of the feedback
counter. The phase/frequency detector measures the phase
error between the fr and fp signals and outputs control signals that are directly proportional to the phase error. The
charge pump then pumps charge into or out of the loop filter
based on the magnitude and direction of the phase error.
The loop filter converts the charge into a stable control
voltage for the VCO. The phase/frequency detector’s function is to adjust the voltage presented to the VCO until the
feedback signal’s frequency and phase match that of the
reference signal. When this “phase-locked” condition exists,
the RF VCO frequency will be N times that of the comparison
frequency, where N is the feedback divider ratio.
1.0 Functional Description
The basic phase-lock-loop (PLL) configuration consists of a
high-stability crystal reference oscillator, a frequency synthesizer such as the National Semiconductor LMX2310/1/2/3U,
a voltage controlled oscillator (VCO), and a passive loop
filter. The frequency synthesizer includes a phase detector, a
current mode charge pump, as well as a programmable
reference divider and feedback frequency divider. The VCO
frequency is established by dividing the crystal reference
signal down via the reference divider to obtain a frequency
that sets the comparison frequency. This reference signal, fr,
is then presented to the input of a phase/frequency detector
and compared with another signal, fp, which was obtained by
20043829
1.1 REFERENCE OSCILLATOR
The reference oscillator frequency for the RF PLL is provided
from the external source via the OSCin pin. The low noise
reference buffer circuit supports frequencies from 2 MHz to
50 MHz with a minimum input sensitivity of 0.5 Vpp. The input
can be driven from an external CMOS or TTL logic gate. The
output of this buffer drives the R COUNTER. The output of
the buffer also connects to an oscillator/buffer circuit. Its
output connects to the OSCout pin. The oscillator/buffer circuit can be used as a buffer to provide the reference frequency to other circuitry. It can also be used as an oscillator
with a crystal/resonator with proper components connected
between OSCin and OSCout pins to generate a reference
frequency.
PLL
Input
Frequency
PLL
Part
Numbers
Allowable
Prescaler
Values
FIN ≤ 1.2 GHz
LMX2310/1/2U
16/17 or
32/33
FIN ≤ 600
MHz
LMX2313U
8/9 or
16/17
The complimentary FIN and FINB input pins drive the input of
a bipolar, differential-pair amplifier. The output of the bipolar,
differential-pair amplifier drives a chain of ECL D-type flipflops in a dual modulus configuration. The output of the
prescaler is used to clock the subsequent programmable
feedback divider. Refer to Section 3.3.2 for details on programming the Prescaler Value.
1.2 REFERENCE DIVIDER (R COUNTER)
The reference divider is comprised of a 15-bit CMOS binary
counter that supports a continuous integer divide range from
2 to 32,767. The divide ratio should be chosen such that the
maximum phase comparison frequency of 10 MHz is not
exceeded. The reference divider circuit is clocked by the
output of the reference buffer circuit. The output of the
reference divider circuit feeds the reference input of the
phase detector circuit. The frequency of the reference input
to the phase detector (also referred to as the comparison
frequency) is equal to reference oscillator frequency divided
by the reference divider ratio. Refer to Section 3.2.1 for
details on programming the R COUNTER.
1.4 FEEDBACK DIVIDER (N COUNTER)
The N COUNTER is clocked by the output of the prescaler.
The N COUNTER is composed of a 13-bit programmable
integer divider. The 5-bit swallow counter is part of the
prescaler. Selecting a 32/33 prescaler provides a minimum
continuous divider range from 992 to 262,143 while selecting
a 16/17 prescaler value allows for continuous divider values
from 240 to 131,071. In the LMX2313U, selecting a 8/9
prescaler provides a minimum continuous divider range from
56 to 65535.
N = (P x NB_CNTR) + NA_CNTR
1.3 PRESCALERS
The LMX2310/1/2U contains a selectable, dual modulus
32/33 and 16/17 prescaler. The LMX2313U contains a selectable, dual modulus 16/17 and 8/9 prescaler.
PLL
Input
Frequency
PLL
Part
Numbers
FIN > 1.2 GHz
LMX2310/1U
www.national.com
FIN = N x Fφ
Definitions
Allowable
Prescaler
Values
32/33
22
Fφ
Phase Detector Comparison Frequency
FIN
RF Input Frequency
P
Prescaler Value
NA_CNTR
A Counter Value
NB_CNTR
B Counter Value
trol the charge pump. The polarity of the pump-up or pumpdown control signals are programmed using the PD_POL
control bit, depending on whether the RF VCO tuning characteristics are positive or negative (see programming description in Section 3.2.2). The phase/frequency detector
has a detection range of −2π to +2π.
(Continued)
1.5 PHASE/FREQUENCY DETECTORS
The phase/frequency detector is driven from the N and R
COUNTER outputs. The maximum frequency at the phase
detector inputs is 10 MHz. The phase detector outputs con-
Phase Comparator and Internal Charge Pump Characteristics
20043804
Note 13: The minimum width of the pump up and pump down current pulses occur at the CPo pin when the loop is phase-locked.
Note 14: The diagram assumes that PD_POL = 1
Note 15: fr is the phase comparator input from the R Divider
Note 16: fp is the phase comparator input from the N Divider
Note 17: CPo is charge pump output
1.6 CHARGE PUMP
The charge pumps directs charge into or out of an external
loop filter. The loop filter converts the charge into a stable
control voltage which is applied to the tuning input of a VCO.
The charge pump steers the VCO control voltage towards VP
during pump-up events and towards GND during pumpdown events. When locked, CPo is primarily in a TRI-STATE
condition with small corrections occurring at the phase comparison rate. The charge pump output current magnitude can
be selected as 1.0 mA or 4.0 mA by programming the
ICPo_4X bits. When TO_CNTR[11:0] = 1, the charge pump
output current magnitude is set to 4.0 mA. Refer to Section
3.2.3 and 3.4.2 for details on programming the charge pump
output current magnitude.
ence divider and the feedback divider circuits. The FoLD
output pin is referenced to the VµC supply. The FoLD0,
FoLD1 and FoLD2 bits are used to select the desired output
function. A complete programming description of the FoLD
output pin is in Section 3.2.5.
1.8.1 Analog Lock Detect
When programmed for analog lock detect, the analog lock
detect status is available on the FoLD output pin. When the
charge pump is inactive, the lock detect output goes to a
high impedance in the open drain configuration and to a VµC
source in a push-pull configuration. It goes low when the
charge pump is active during a comparison cycle. The analog lock detect status can be programmed in either an open
drain or push-pull configuration. The push-pull output is referenced to VµC.
1.7 MICROWIRE SERIAL INTERFACE
The programmable register set is accessed through the
MICROWIRE serial interface. The interface is comprised of
three signal pins: CLOCK, DATA and LE (Latch Enable). The
MICROWIRE circuitry is referenced to VµC, which allows the
circuitry to operate down to a 1.72V source. Serial data is
clocked into a 22-bit shift register from DATA on the rising
edge of CLOCK. The serial data is clocked in MSB first. The
last two bits decode the internal register address. On the
rising edge of LE, the data stored in the shift register is
loaded into one of the three latches based on the address
bits. The synthesizer can be programmed even in the powerdown state. A complete programming description is in Section 3.0.
1.8.2 Digital Lock Detect
When programmed for digital lock detect, the digital lock
detect status is available on the FoLD pin. The digital lock
detect filter compares the phase difference of the inputs from
the phase detector to a RC generated delay of approximately 15 ns. To enter the locked state (LD = High), the
phase error must be less than the 15 ns RC delay for 5
consecutive reference cycles. Once in lock, the RC delay is
changed to approximately 30 ns. To exit the locked state, the
phase error must be greater than the 30 ns RC delay. When
a PLL is in power-down mode, the respective lock detect
output is always low. A flow chart of the digital lock detect
filter follows:
1.8 MULTI-FUNCTION OUTPUTS
The LMX2310/1/2/3U FoLD output pin is a multi-function
output that can be configured as an analog lock detect, a
digital lock detect, and a monitor of the output of the refer-
23
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
1.0 Functional Description
LMX2310U/LMX2311U/LMX2312U/LMX2313U
1.0 Functional Description
(Continued)
20043805
1.9 Fastlock™ OUTPUT
The FL pin can be used as the Fastlock output. The FL pin
can also be programmed as constant low, constant high
(referenced to VCC), or constant high impedance, selectable
through the T register. When the device is configured in
Fastlock mode, the charge pump current can be increased
4x while maintaining loop stability by synchronously switching a parallel loop filter resistor to ground with the FL pin,
resulting in a ∼2x increase in loop bandwidth. The loop
bandwidth, the zero gain crossover point of the open loop
gain, is effectively shifted up in frequency by a factor of the
square root of 4 = 2 during Fastlock mode. For ω' = 2 ω, the
phase margin during Fastlock also will remain constant. The
user calculates the loop filter component values for the
normal steady state considerations. The device configuration ensures that as long as a second resistor, equal to the
primary resistor value, is wired in appropriately, the loop will
lock faster without any additional stability considerations.
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The PLL can be configured to be in either the Fastlock mode
continuously or in the Fastlock mode that uses a timeout
counter to switch it back to the normal mode. In the Fastlock
mode the charge pump current is set to 4 mA and the FL pin
is set low. If the user sets the PLL to be in the Fastlock mode
continuously he can send the R register with CPo_4X set low
(R[18] = 0) and sets TO_CNTR[11:0] to 1. The user can set
the PLL to normal mode (1 mA mode and set the FL pin to
TRI-STATE mode) by programming TO_CNTR[11:0] to 0. If
the user elects to use the timeout counter, he can program
the timeout counter from 4 to 4095. The timeout counter will
count down the programmed number of phase detector reference cycles. After the programmed number of phase detector reference cycles is reached, it will automatically set
the charge pump current to the 1 mA mode and set the FL
pin to TRI-STATE mode. A complete programming description is in Section 3.4.2.
24
The LMX2310/1/2/3U are power controlled through logical
control of the CE pin in conjunction with programming of the
PDWN and CPo_TRI bits. A truth table is provided that
describes how the state of the CE pin, the PDWN bit and
CPo_TRI bit set the operating mode of the device. A complete programming description of Power-Down is provided in
Section 3.3.1.
CE
PWDN CPo_TRI
Operating Mode
0
X
X
Power-down (Asynchronous)
1
0
0
Normal Operation
1
1
0
Power-down (Synchronous)
1
1
1
Power-down (Asynchronous)
X = Don’t Care
When the device enters the power-down mode, the oscillator
buffer, RF prescaler, phase detector, and charge pump circuits are all disabled. The OSCIN, CPo, FIN, FINB, LD pins
are all forced to a high impedance state. The reference
divider and feedback divider circuits are disabled and held at
The asynchronous power-down function is NOT gated by the
completion of a charge pump pulse event. When the device
is configured for asynchronous power-down, the part will go
into power-down mode immediately.
3.0 Programming Description
3.1 MICROWIRE INTERFACE
The MICROWIRE interface is comprised of a 22-bit shift register and three control registers. The shift register consists of a 20-bit
DATA field and a 2-bit address (ADDR) field as shown below. Data is loaded into the shift register on the rising edges of the
CLOCK signal MSB first. When Latch Enable transitions HIGH, data stored in the shift register is loaded into either the R, N or
T register depending on the state of the ADDR bit. The DATA field assignments for the R, N and T registers are shown in Section
3.1.1.
MSB
LSB
DATA
ADDRESS
21
2
0
ADDR
Target Register
0
R register
1
N register
2
T register
3.1.1 Register Map
Register
Most Significant Bit
21
20
19
SHIFT REGISTER BIT LOCATION
18
17
16
15
14
13
12
11
10
Least Significant Bit
9
8
7
6
5
4
3
FoLD1
FoLD0
N
PWDN
P
T
0
0
CPo_
TRI
CP0_
4x
PD_
POL
0
0
0
R_CNTR[14:0]
B_CNTR[12:0]
0
0
FoLD2
25
1
0
Address
Field
Data Field
R
2
A_CNTR[4:0]
TO_CNTR[11:0]
0
0
0
1
1
0
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
the load point during power-down. When the device is programmed to normal operation, the oscillator buffer, RF prescaler, phase detector, and charge pump circuits are all powered on. The feedback divider and the reference divider are
held at the load point. This allows the RF prescaler, feedback
divider, reference oscillator, the reference divider and prescaler circuitry to reach proper bias levels. After a 1.5 µs
delay, the feedback and reference divider are enabled and
they resume counting in “close” alignment (The maximum
error is one prescaler cycle). The MICROWIRE control register remains active and capable of loading and latching in
data while in the power-down mode.
The synchronous power-down function is gated by the
charge pump. When the device is configured for synchronous power-down, the device will enter the power-down
mode upon the completion of the next charge pump pulse
event.
2.0 Power-Down
LMX2310U/LMX2311U/LMX2312U/LMX2313U
3.0 Programming Description
(Continued)
3.2 R REGISTER
The R register contains the R_CNTR control word and PD_POL, CPo_4X, CP_TRI, FoLD0, FoLD1 control bits. The detailed
descriptions and programming information for each control word is discussed in the following sections.
Register Most Significant Bit
21
20
SHIFT REGISTER BIT LOCATION
19
18
17
16
15
14
13
12
11
Least Significant Bit
10
9
8
7
6
5
4
3
2
1
Address
Field
Data Field
R
FoLD1
FoLD0
CPO_
TRI
CPO_
4X
0
PD_
POL
R_CNTR[14:0]
0
0
3.2.1 R_CNTR[14:0]
Reference Divider (R COUNTER)
R[16:2]
The reference divider can be programmed to support divide ratios from 2 to 32,767. Divide ratios of less than 2 are prohibited.
Divider Value
R_CNTR[14:0]
2
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
3
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
•
32,767
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
1
•
3.2.2 PD_POL
Phase Detector Polarity
R[17]
The PD_POL control bit is used to set the polarity of the phase detector based on the VCO tuning characteristic.
Control Bit Register Location
PD_POL
R[17]
Function
Description
0
1
Phase Detector Polarity Negative VCO Tuning Characteristic Positive VCO Tuning Characteristic
VCO Characteristics
20043809
3.2.3 CPo_4X
Charge Pump Output Current
R[18]
The CPo_4X control bit allows the charge pump output current magnitude to be switched from 1 mA to 4 mA. This happens
asynchronously or immediately with the change in CPo_4X bit.
Function
Control Bit
Register Location
Description
CPo_4X
R[18]
Charge Pump Output Current Magnitude
0
1
1X Current
4X Current
3.2.4 CPo_TRI
Charge Pump TRI-STATE
R[19]
The CPo_TRI control bit allows the charge pump to be switched between a normal operating mode and a high impedance output
state. This happens asynchronously or immediately with the change in CPo_TRI bit.
Control Bit
Register Location
Description
CPo_TRI
R[19]
Charge Pump TRI-STATE
www.national.com
Function
0
1
Charge Pump Operates Normal
Charge Pump Output in High
Impedance State
26
(Continued)
3.2.5 FoLD2,1,0
T[14],R[21],R[20]
FoLD Output Truth Table
LMX2310U/LMX2311U/LMX2312U/LMX2313U
3.0 Programming Description
The FoLD2, FoLD1 and FoLD0 are used to select which signal is routed to FoLD pin.
T[14]
R[21]
R[20]
FoLD2
FoLD1
FoLD0
0
0
0
Disabled (TRI-STATE FoLD)
0
0
1
Lock Detect — Analog (Push/Pull), Reference to Vµc
0
1
0
Lock Detect — Analog (Open Drain)
0
1
1
Reset R and N Dividers and TRI-STATE Charge Pump
1
0
0
Lock Detect — Digital (Push/Pull), Reference to VµC
1
0
1
R COUNTER Output (Push/Pull), Reference to VµC
1
1
0
N Counter Output (Push/Pull), Reference to VµC
1
1
1
Reserved (Do Not Use)
FoLD Output State
3.3 N REGISTER
The N register contains the PWDN (Power-Down), P (Prescaler), NA_CNTR, and NB_CNTR control words. The detailed
descriptions and programming information for each control word is discussed in the following sections.
Register
Most Significant Bit
21
20
19
SHIFT REGISTER BIT LOCATION
18
17
16
15
14
13
12
11
10
9
8
Least Significant Bit
7
6
5
4
3
PWDN
P
1
0
Address
Field
Data Field
N
2
B_CNTR[12:0]
A_CNTR[4:0]
0
1
3.3.1 PWDN
Power-Down
N[21]
The PWDN control bit along with CPo_TRI control bit is used to power-down the PLL. The LMX2310/1/2/3U can be synchronous
or asynchronous powered down by first setting the CPo_TRI bit and then setting the PWDN bit. To power up from the synchronous
Power-Down mode, the CPo_TRI bit will have to be reset to 0.
N[21]
R[19]
PWDN
CPO_TRI
0
0
Normal Operation
1
0
Power-down (Synchronous)
1
1
Power-down (Asynchronous)
Operating Mode
3.3.2 P
Prescaler
N[20]
The LMX2310/1/2/3U contains two dual modulus prescalers. The P control bit is used to set the prescaler value.
N[20]
Prescaler Value
LMX2310/1/2U
Prescaler Value
LMX2313U
0
16/17
8/9
1
32/33
16/17
PLL Input Frequency
Allowable Prescaler Values
FIN > 1.2 GHz
32/33
FIN ≤ 1.2 GHz
16/17 or 32/33
FIN ≤ 600 MHz
8/9 or 16/17
27
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LMX2310U/LMX2311U/LMX2312U/LMX2313U
3.0 Programming Description
3.3.3 B_CNTR[12:0]
B COUNTER
(Continued)
N[19:7]
The NB_CNTR control word is used to program the B counter. The B counter is a 13-bit binary counter used in the programmable
feedback divider. The B counter can be programmed to values ranging from 3 to 8,191. See Section 1.4 for details on how the
value of the B counter should be selected.
Divider Value
B_CNTR[12:0]
3
0
0
0
0
0
0
0
0
0
0
0
1
1
4
0
0
0
0
0
0
0
0
0
0
1
0
1
•
•
•
•
•
•
•
•
•
•
•
•
•
•
8,191
1
1
1
1
1
1
1
1
1
1
1
1
1
NOTE: B counter divide ratio must be ≥ 3.
3.3.4 A_CNTR[4:0]
A Counter
N[6:2]
The NA_CNTR control word is used to program the A counter. The A counter is a 5-bit swallow counter used in the programmable
feedback divider. The A counter can be programmed to values ranging from 0 to 31. See Section 1.4 for details on how the value
of the A counter should be selected.
Divide
Ratio
A_CNTR[4:0]
0
0
0
0
0
0
1
0
0
0
0
1
•
•
•
•
•
•
31
1
1
1
1
1
NOTES: A counter divide ratio must be ≤ P and A counter divide ratio must be ≤ B counter divide ratio.
3.4 T REGISTER
The T register contains the TO_CNTR control word and FoLD2 control bit. The detailed descriptions and programming
information for each control word is discussed in the following sections.
Register
Most Significant Bit
21
20
19
18
SHIFT REGISTER BIT LOCATION
17
16
15
14
13
12
11
10
9
Least Significant Bit
8
7
6
5
4
3
2
Data Field
T
0
0
0
0
0
0
0
FoLD2
TO_CNTR[11:0]
3.4.1 FoLD2
FoLD Output (P/O Output Truth Table)
See Section 3.2.5 for FoLD Output Truth Table details.
1
0
Address
Field
1
0
T[14]
3.4.2 TO_CNTR[11:0]
Timeout Counter Table
T[13:2]
When the Fastlock Timeout counter (TO_CNTR) is loaded with 0, Fastlock is off, the FL pin will be in TRI-STATE mode, and the
charge pump current will be the value specified by the Charge Pump Magnitude bit, R[18]. When the Timeout counter is loaded
with 1, the FL pin is 0 (pulled low) and the charge pump current will be at the 4X state. When the Timeout counter is loaded with
2, the FL pin will again be set to 0 (pulled low), but the charge pump current will be controlled by R[18]. When the Timeout counter
is loaded with 3, the FL pin is 1 (pulled high) with the charge pump current will be controlled by R[18]. When loaded with 4 through
4095, Fastlock is active and will time-out after the specified number of phase detector events.
Count
TO_CNTR[11:0]
FL Pin Forced TRI-STATE
0
0
0
0
0
0
0
0
0
0
0
0
CP current controlled by R[18]
FL Pin Forced Low
0
0
0
0
0
0
0
0
0
0
0
1
CP = 4 mA (manual Fastlock mode)
FL Pin Forced Low
0
0
0
0
0
0
0
0
0
0
1
0
CP current controlled by R[18]
FL Pin Forced High
0
0
0
0
0
0
0
0
0
0
1
1
CP current controlled by R[18]
Min Count (4)
0
0
0
0
0
0
0
0
0
1
0
0
•
Max Count (4095)
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
•
1
www.national.com
Notes
28
CP Current set to 4 mA, switches to 1 mA
when count reaches 0
inches (millimeters) unless otherwise noted
20-Pin Thin Chip Scale Package
Order Number LMX2310U, LMX2311U, LMX2312U or LMX2313U
NS Package Number SLD20A
For Tape and Reel (2500 Units Per Reel) Order Numbers: LMX2310USLDX, LMX2311USLDX, LMX2312USLDX,
LMX2313USLDX
LIFE SUPPORT POLICY
NATIONAL’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT
DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF THE PRESIDENT AND GENERAL
COUNSEL OF NATIONAL SEMICONDUCTOR CORPORATION. As used herein:
1. Life support devices or systems are devices or
systems which, (a) are intended for surgical implant
into the body, or (b) support or sustain life, and
whose failure to perform when properly used in
accordance with instructions for use provided in the
labeling, can be reasonably expected to result in a
significant injury to the user.
2. A critical component is any component of a life
support device or system whose failure to perform
can be reasonably expected to cause the failure of
the life support device or system, or to affect its
safety or effectiveness.
BANNED SUBSTANCE COMPLIANCE
National Semiconductor certifies that the products and packing materials meet the provisions of the Customer Products
Stewardship Specification (CSP-9-111C2) and the Banned Substances and Materials of Interest Specification
(CSP-9-111S2) and contain no ‘‘Banned Substances’’ as defined in CSP-9-111S2.
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National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves the right at any time without notice to change said circuitry and specifications.
LMX2310U/LMX2311U/LMX2312U/LMX2313U PLLatinum Ultra Low Power Frequency Synthesizer
for RF Personal Communications
Physical Dimensions