NSC LMX2364TMX

LMX2364
2.6 GHz PLLatinum Fractional RF Frequency Synthesizer
with 850 MHz Integer IF Frequency Synthesizer
General Description
The LMX2364 integrates a high performance 2.6 GHz fractional frequency synthesizer with a 850 MHz low power
Integer-N frequency synthesizer. Designed for use in a local
oscillator subsystem of a radio transceiver, the LMX2364
generates very stable, low noise control signals for UHF and
VHF voltage controlled oscillators. It is fabricated using National’s high performance BiCMOS process.
The RF Synthesizer supports both fractional and integer
modes. The N counter contains a selectable, quadruple
modulus prescaler and can support fractional denominators
from 1 to 128. A flexible, 4 level programmable charge pump
supplies output current magnitudes ranging from 1 mA to 16
mA. Only a single word write is required to power up and
tune the synthesizer to a new frequency.
High performance FastLock™ technology makes the
LMX2364 an excellent choice for applications requiring aggressive lock time while maintaining excellent phase noise
and spurious performance. The combination of the improved
FastLock circuitry, the enhanced fractional compensation
engine, and the programmable charge pump architecture
gives the designer maximum freedom to optimize the performance of the synthesizer for the target application. Integrated timeout counters greatly simplify the programming
aspects of FastLock. These timeout counters reduce the
demands on the microcontroller by automatically disengaging FastLock after a perscribed number of reference cycles
of the phase detector.
The IF synthesizer includes a fixed 8/9 dual modulus prescaler, a two level programmable charge pump, and dedicated FastLock circuitry with an integrated timeout counter.
The LMX2364 offers many performance enhancements over
the LMX2354. Improvements in the fractional compensation
make the spurs on the LMX2364 approximately 6 dB better
in a typical application. The higher and more flexible fractional modulus combined with the higher charge pump currents result in phase noise improvements on the order of 10
dB. The cycle slip reduction circuitry of the LMX2364 is both
easy to use and effective in reducing cycle slipping and
allows one to use very high phase detector frequencies
without degrading lock times.
Serial data is transferred to the device via a three-wire
interface (DATA, LE, CLK). The low voltage logic interface
allows direct connection to 1.8 Volt and 3.0 Volt devices.
Supply voltages from 2.7V to 5.5V are supported. Independent charge pump supplies for each synthesizer allows the
designer to optimize the bias level for the selected VCO. The
LMX2364 consumes 5.0 mA (typical) of current in integer
mode and 7.2 mA (typical) in fractional mode. The LMX2364
is available in a 24 Pin Ultra Thin CSP package and 24 Pin
TSSOP Package.
Features
n RF Synthesizer supports both Fractional and Integer
Operating Modes
n Pin Compatible upgrade for LMX2354
n 2.7V to 5.5V operation
n Pin and programmable power down
n Fractional N divider supports fractional denominators
ranging from 1 through 128
n Supports Integer Mode Operation
n Programmable charge pump current levels
RF: 4 level, 1 – 16 mA
IF: 2 level, 100/800 uA
n FastLock Technology with integrated timeout counters
n Digital filtered & analog lock detect output
n FastLock Glitch Reduction Technology
n Enhanced Low Noise Fractional Compensation Engine
n Low voltage programming interface allows direct
connection to 1.8V logic
Applications
n
n
n
n
n
n
n
n
n
Digital Cellular
GPRS
IS-136
GAIT
PDC
EDGE
CDMA
Zero blind slot TDMA systems
Cable TV Tuners (CATV)
FastLock™ is a trademark of National Semiconductor Corporation.
TRI-STATE ® is a registered trademark of National Semiconductor Corporation.
© 2003 National Semiconductor Corporation
DS200506
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LMX2364 2.6 GHz PLLatinum Fractional RF Frequency Synthesizer with 850 MHz Integer-N IF
Frequency Synthesizer
July 2003
LMX2364
Functional Block Diagram
20050601
Connection Diagrams
24-Pin TSSOP (TM) Package
Ultra Thin 24-Pin CSP (SLE) Package
20050622
20050602
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2
LMX2364
Pin Descriptions
Pin Number
TSSOP
2
SLE
1
Pin
VccRF
Description
RF PLL power supply voltage input. Must be equal to VVccIF. 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.
3
2
VcpRF
Power supply for RF charge pump. Must be ≥ VVccRF and VVccIF.
4
3
CPoutRF
RF charge pump output.
5
4
GND
Ground for RF PLL digital circuitry.
6
5
FinRF
RF prescaler input. Small signal input from the VCO.
7
6
FinRF*
RF prescaler complementary input. For single-ended operation, a bypass capacitor
should be placed as close as possible to this pin and be connected directly to the
ground plane.
8
7
GND
Ground for RF PLL analog circuitry.
9
8
OSCinRF
RF R counter input. Has a VCC/2 input threshold when configured as an input and can
be driven from an external CMOS or TTL logic gate.
10
9
OSCinIF
Oscillator input which can be configured to drive both the IF and RF R counter inputs
or only the IF R counter depending on the state of the OSC programming bit.
11
10
Ftest/LD
Programmable multiplexed output pin. Can function as general purpose CMOS
TRI-STATE ® I/O, analog lock detect output, digital filtered lock detect output, or N & R
divider output.
12
11
ENRF
RF PLL Enable. Powers down RF N and R counters, prescaler, and TRI-STATE
charge pump output when LOW, regardless of the state RF_PD bit. Bringing ENRF
high powers up RF PLL depending on the state of RF_PD control bit.
13
12
ENIF
IF PLL Enable. Powers down IF N and R counters, prescaler, and will TRI-STATE the
charge pump output when LOW, regardless of the state IF_PD bit. Bringing ENIF high
powers up IF PLL depending on the state of IF_PD control bit.
14
13
CLK
High impedance CMOS Clock input. Data for the control registers is clocked into the
24-bit shift register on the rising edge.
15
14
DATA
Binary serial data input. Data entered MSB first. The last three bits are the control
bits. High impedance CMOS input.
16
15
LE
Latch enable. High impedance CMOS input. Data stored in the shift register is loaded
into one of the 7 internal latches when LE goes HIGH.
17
16
GND
Ground for IF analog circuitry.
18
17
FinIF*
IF prescaler complementary input. For single-ended operation, a bypass capacitor
should be placed as close as possible to this pin and be connected directly to the
ground.
19
18
FinIF
IF prescaler input. Small signal input from the VCO.
20
19
GND
Ground for IF digital circuitry.
21
20
CPoutIF
IF charge pump output.
22
21
VcpIF
Power supply for IF charge pump. Must be ≥ VVccRF and VVccIF.
23
22
VccIF
IF power supply voltage input. Must be equal to VVccRF. 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.
24
23
FLoutIF
IF FastLock Output. Also functions as Programmable TRI-STATE CMOS output.
1
24
FLoutRF
RF FastLock Output. Also functions as Programmable TRI-STATE CMOS output.
3
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LMX2364
Absolute Maximum Ratings
Parameter
(Notes 1, 2)
Value
Symbol
Power Supply Voltage
Min
Typ
Units
Max
VVcc
−0.3
6.5
V
VVcp
−0.3
6.5
V
VCC
−0.3
VCC + 0.3
V
Storage Temperature Range
Ts
−65
+150
˚C
Lead Temperature (Solder 4 sec.)
TL
+260
˚C
Voltage on any pin with GND = 0V
Recommended Operating Conditions
Value
Parameter
Symbol
Power Supply Voltage
VVccRF
2.7
5.5
V
Operating Temperature
Min
Typ
Units
Max
VVccIF
VVccRF
VVccRF
V
VVcpRF
VVccRF
5.5
V
VVcpIF
VCCIF
5.5
V
TA
−40
+85
˚C
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 test conditions, see the Electrical Characteristics. The
guaranteed specifications apply only for the test conditions listed.
Note 2: This Device is a high performance RF integrated circuit with an ESD rating < 2 kV and is ESD sensitive. Handling and assembly of this device should only
be done at ESD-free workstations.
Electrical Characteristics
Symbol
(VVcc = VVcp = 3.0V; −40˚C ≤ TA ≤ +85˚C except as specified)
Parameter
Conditions
Power Supply Current, RF
Synthesizer, Integer Mode
Value
Min
Units
Typ
Max
VENIF=VCLK=VDATA=VLE = LOW
VENRFV= HIGH
FE = 0
5.0
6.3
mA
Power Supply Current, RF
Synthesizer, Fractional
Mode
VENIF=VCLK,=VDATA=VLE=0 V
VENRF=HIGH
FE = 1
7.2
8.0
mA
ICCIF
Power Supply Current, IF
Synthesizer
VENRF=VCLK=VDATA=VLE=LOW
VENIF=HIGH
2.4
3.2
mA
ICCIF PD
Power Down Current
VENRF=VENIF= LOW
VCLK=VDATA=VLE= LOW
5.0
20
µA
ICC PARAMETERS
ICCRF
RF SYNTHESIZER PARAMETERS
fFinRF
N
R
Operating Frequency
500
1200
MHz
Prescaler = 16/17/20/21
1200
2600
MHz
4095
Continuous N Divider
Range, Fractional Mode
Prescaler = 8/9/12/13
40
Prescaler = 16/17/20/21
80
8191
Continuous N Divider
Range, Integer Mode
Prescaler = 8/9/12/13
40
266,239
Prescaler = 16/17/20/21
80
532,479
R Divider Range,
Fractional Mode
1
511
R Divider Range, Integer
Mode (Note 3)
1
64,897
fCOMP
Phase Detector Frequency
pFinRF
RF Input Sensitivity
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Prescaler = 8/9/12/13
15
MHz
VCC = 3.0V
−15
0
dBm
VCC = 5.0V
−10
0
dBm
4
Symbol
Parameter
Conditions
(Continued)
Value
Min
Typ
Units
Max
RF SYNTHESIZER PARAMETERS
ICPoutRFSRCE
ICPoutRFSINK
RF Charge Pump Source
Current
RF Charge Pump Sink
Current
RF_CP=0
VCPoutRF = VVcpRF /2
1
mA
RF_CP=1
VCPoutRF = VVcpRF /2
4
mA
RF_CP=2
VCPoutRF = VVcpRF /2
8
mA
RF_CP=3
VCPoutRF = VVcpRF /2
16
mA
RF_CP=0
VCPoutRF = VVcpRF /2
−1
mA
RF_CP=1
VCPoutRF = VVcpRF /2
−4
mA
RF_CP=2
VCPoutRF = VVcpRF /2
−8
mA
RF_CP=3
VCPoutRF = VVcpRF /2
−16
mA
ICPoutRFTRI
RF Charge Pump
TRI-STATE Current
0.5 ≤ VCPoutRF ≤ VVcpRF −0.5
ICPoutRF%MIS
RF CP Sink vs. CP Source
Mismatch
VCPoutRF = VVcpRF /2
TA = 25˚C
ICPoutRF%V
RF CP Current vs. CP
Voltage
0.5 ≤ VCPoutRF ≤ VVcpRF −0.5
TA = 25˚C
RF_CP=0, 1, or 2
RF CP Current vs.
Temperature
VPCPoutRF = VVcpRF /2
ICPoutRF%TEMP
−10.0
10.0
nA
3.5
%
5
10
%
8
10
%
MHz
IF SYNTHESIZER PARAMETERS
fFinIF
Operating Frequency
50
850
N IF
Continuous N Divider
Range
56
262,143
R IF
R Divider Range
3
32,767
fCOMP
Phase Detector Frequency
pFinIF
IF Input Sensitivity
2.7 ≤ VVcc ≤ 5.5V
ICPoutIFSRCE
IF Charge Pump Source
Current
IF_CP = 0
VCPoutIF = VVcpIF /2
100
µA
IF_CP = 1
VCPoutIF = VVcpIF /2
800
µA
IF_CP = 0
VCPoutIF = VVcpIF /2
−100
µA
IF_CP = 1
VCPoutIF = VVcpIF /2
−800
µA
ICPoutIFSINK
IF Charge Pump Sink
Current
−10
ICPoutTRI
IF Charge Pump
TRI-STATE Current
0.5 ≤ VCPout ≤ VVcpIF −0.5
ICPoutIF%MIS
IF CP Sink vs. CP Source
Mismatch
VCPoutIF = VVcpIF /2
TA = 25˚C
5
ICPoutIF%V
IF CP Current vs. CP
Voltage
0.5 ≤ VCPoutIF ≤ VVcpIF −0.5
TA = 25˚C
5
ICPoutIF%TEMP
IF CP Current vs.
Temperature
VCPoutIF = VVcpIF /2
5
−2.0
10
MHz
0
dBm
2.0
8
nA
%
10
%
%
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LMX2364
Electrical Characteristics (VVcc = VVcp = 3.0V; −40˚C ≤ TA ≤ +85˚C except as specified)
LMX2364
Electrical Characteristics (VVcc = VVcp = 3.0V; −40˚C ≤ TA ≤ +85˚C except as specified)
Symbol
Parameter
(Continued)
Value
Conditions
Min
Typ
Max
Units
OSCILLATOR PARAMETERS
fOSC
Oscillator Operating
Frequency
vOSC
Oscillator Sensitivity
OSCinRF, OSCinIF
IOSC
Oscillator Input Current
VOSC = VVcc
VOSC = 0V
2
110
MHz
0.5
VVcc
V
100
µA
−100
µA
DIGITAL INTERFACE (DATA, CLK, LE, ENIF, ENRF, Ftest/LD, FLoutRF, FLoutIF)
VIH
High-Level Input Voltage
VIL
Low-Level Input Voltage
2.7 ≤ VVcc ≤ 3.2
1.6
V
3.2 < VVcc ≤ 5.5
2
V
0.4
V
IIH
High-Level Input Current
VIH = VCC
−1.0
1.0
µA
IIL
Low-Level Input Current
VIL = 0
−1.0
1.0
µA
VOH
High-Level Output Voltage
IOH = −500 µA
VOL
Low-Level Output Voltage
IOL = 500 µA
VCC −0.4
V
0.4
V
MICROWIRE INTERFACE TIMING
TCS
Data to Clock Set Up Time
See Data Input Timing
50
ns
TCH
Data to Clock Hold Time
See Data Input Timing
10
ns
TCWH
Clock Pulse Width High
See Data Input Timing
50
ns
TCWL
Clock Pulse Width Low
See Data Input Timing
50
ns
TES
Clock to Load Enable Set
Up Time
See Data Input Timing
50
ns
TEW
Load Enable Pulse Width
See Data Input Timing
50
ns
RF Synthesizer’s
Normalized Phase Noise
Contribution, Fractional
Mode (Note 4)
RF_OM = 1 (Fractional Mode)
f = 3 KHz
TCXO Reference Source
RF_CP = 1 (4 mA)
VENIF = LOW
−208
dBc/Hz
RF Synthesizer’s
Normalized Phase Noise
Contribution, Integer Mode
(Note 4)
RF_OM = 0 (Integer Mode)
f = 3 KHz
TCXO Reference Source
RF_CP = 2 (4 mA)
VENIF = LOW
−215
dBc/Hz
IF Synthesizer’s
Normalized Phase Noise
Contribution (Note 4)
f = 3 KHz
TCXO Reference Source
IF_CP = 1 (800 mA)
VENRF = LOW
−212
dBc/Hz
PHASE NOISE
LF1Hz(f) RF
LF1Hz(f) IF
Note 3: Some reference divider ratios between the minimum and maximum are not realizable. See the section on R divider programming for more details.
Note 4: Normalized Phase Noise Contribution is defined as: LF1Hz(f) = L(f) – 20·log(N) – 10log(fCOMP) where L(f) is defined as the single side band phase noise
measured at an offset frequency, f, in a 1 Hz Bandwidth. The offset frequency, f, must be chosen sufficiently smaller than the PLL’s loop bandwidth, yet large enough
to avoid substantial phase noise contribution from the reference source.
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6
LMX2364
Serial Data Input Timing
20050603
Note: Data is shifted MSB first into the MICROWIRE shift register on the rising edge of the Clock signal. When a rising edge is seen on the LE pulse, these values
are actually loaded into the PLL target registers.
Since the data is clocked in on the rising edge of the LE pulse, the programming time of one register can be eliminated by sending the Data and Clock signals
in advance and delaying the LE pulse until it is desired that the values are to be loaded.
Note: The Serial Data Input Timing is tested using a symmetrical waveform around VCC/2. The test waveform has an edge rate of 0.6 V/ns with amplitudes of 2.2V
@ VCC=2.7V and 2.6V @ VCC = 3.3V.
7
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LMX2364
Typical Performance Characteristics
RF PLL 1 Hz Normalized Phase Noise (Fractional Mode)
20050672
IF PLL 1 Hz Normalized Phase Noise
20050673
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8
LMX2364
Typical Performance Characteristics
(Continued)
RF N Counter Sensitivity
TA = 25˚C
20050645
RF N Counter Sensitivity
Vcc = 3.0V
20050646
9
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LMX2364
Typical Performance Characteristics
(Continued)
IF N Counter Sensitivity
TA = 25˚C
20050647
IF N Counter Sensitivity
Vcc = 3.0V
20050648
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10
LMX2364
Typical Performance Characteristics
(Continued)
OSCinRF Counter Sensitivity
TA = 25˚C
20050649
OSCinRF Counter Sensitivity
Vcc = 3.0V
20050650
11
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LMX2364
Typical Performance Characteristics
(Continued)
OSCinIF Counter Sensitivity
TA = 25˚C
20050651
OSCinIF Counter Sensitivity
Vcc = 3.0V
20050652
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12
LMX2364
Input Impedance: FinRF Pin
CSP Package
TSSOP Package
20050653
20050656
FinRF Input Impedance (Ohms)
Frequency (MHz)
CSP Package
TSSOP Package
Real
Imaginary
Real
Imaginary
500
195
-234
278
-215
750
128
-183
213
-196
1000
98
-152
151
-173
1250
77
-125
96
-133
1500
67
-106
63
-99
1750
59
-92
44
-82
2000
53
-81
35
-62
2250
46
-80
26
-53
2500
43
-67
21
-46
2750
41
-61
17
-36
3000
38
-58
15
-26
13
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LMX2364
Input Impedance: FinIF Pin
CSP Package
TSSOP Package
20050657
20050654
FinIF Input Impedance (ohms)
Frequency (MHz)
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CSP Package
TSSOP Package
Real
Imaginary
Real
Imaginary
100
504
-279
505
-222
200
374
-280
414
-205
300
283
-270
349
-198
400
222
-250
295
-194
500
179
-230
243
-190
600
150
-209
190
-183
700
129
-193
141
-168
800
112
-176
110
-151
900
99
-163
86
-138
1000
98
-151
72
-125
1100
82
-140
65
-118
1200
76
-131
64
-116
14
LMX2364
Input Impedance: OSCinIF Pin
CSP Package
TSSOP Package
20050655
20050658
OSCinIF Input Impedance (ohms)
Frequency
(MHz)
CSP Package
Powered Up
TSSOP Package
Powered Down
Powered Up
Powered Down
Real
Imaginary
Real
Imaginary
Real
Imaginary
Real
Imaginary
10
338
-2741
143
-3239
326
-2100
147
-2400
25
130
-1098
92
-1281
112
-909
84
-1100
50
97
-552
81
-645
86
-463
75
-538
75
89
-366
77
-428
81
-320
71
-372
100
84
-276
75
-322
81
-247
72
-284
110
83
-251
75
-292
82
-230
76
-261
15
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LMX2364
Typical Performance
Characteristics
Total Current Consumption
RF_OM=1
20050660
Powerdown Current
VENRF = VENIF = 0V
20050661
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16
LMX2364
Typical Performance Characteristics
(Continued)
RF Charge Pump Current
VVcpRF = 3.0V
20050667
RF Charge Pump Current
VVcpRF = 5.0V
20050668
17
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LMX2364
Typical Performance Characteristics
(Continued)
IF Charge Pump Current
VVcpIF = 3.0V
20050665
IF Charge Pump Current
VVcpIF = 5.0V
20050666
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18
LMX2364
Typical Performance Characteristics
(Continued)
Charge Pump Leakage
RF PLL
20050664
Charge Pump Leakage
IF PLL
20050663
19
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LMX2364
Test Setup Procedures
Sensitivity
20050674
Frequency Input Pin
DC Blocking Capacitor
Corresponding Counter
Default Counter Value
OSCinIF
1 nF
IF_R/RF_R
5000
9 (IF R/2)
FinIF
100 pF
IF_N
5000
10 (IF N/2)
OSCinRF
1 nF
RF_R
50
11 (RF R/2)
FinRF
100 pF
RF_N
50
12 (RF N/2)
Sensitivity is defined as the power level limits beyond which
the output of the counter being tested is off by 1 Hz or more
of its expected value. It is typically measured over frequency,
voltage, and temperature. In order to test sensitivity, the
MUX[3:0] word is programmed to the appropriate value. The
counter value isthen programmed to a fixed value and a
frequency counter is set to monitor the frequency of this pin.
The expected frequency at the Ftest/LD pin should be the
signal generator frequency divided by twice the corresponding counter value. The factor of two comes in because the
LMX2364 has a flip-flop which divides this frequency by two
to make the duty cycle 50% in order to make it easier to read
with the frequency counter. The frequency counter input
impedance should be set to high impedance.
In order to perform the measurement, the temperature, frequency, and voltage is set to a fixed value and the power
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MUX Value
level of the signal is varied. Note that the power level at the
part is assumed to be 4 dB less than the signal generator
power level. This accounts for 1 dB for cable losses and 3 dB
for the pad. The power level range where the frequency is
correct at the Ftest/LD pin to within 1 Hz accuracy is recorded for the sensitivity limits. The temperature, frequency,
and voltage can be varied in order to produce a family of
sensitivity curves. Since this is an open-loop test, the charge
pump is set to TRI-STATE and the unused side of the PLL
(RF or IF) is powered down when not being tested.
For this part, there are actually four frequency input pins,
although there is only one frequency test pin (Ftest/LD). The
conditions specific to each pin are show above.
20
LMX2364
Charge Pump Currents
20050675
The above block diagram shows the test procedure for testing the RF and IF charge pumps. These tests include absolute current level, mismatch, and leakage. In order to measure the charge pump currents, a signal is applied to the high
frequency input pins. The reason for this is to guarantee that
the phase detector gets enough transitions in order to be
able to change states. If no signal is applied, it is possible
that the charge pump current reading will be low due to the
fact that the duty cycle is not 100%. The OSCinIF Pin is tied
to the supply. The charge pump currents can be measured
by simply programming the phase detector to the necessary
polarity. For instance, in order to measure the RF charge
pump current, a 10 MHz signal is applied to the FinRF pin.
The source current can be measured by setting the RF PLL
phase detector to a positive polarity, and the sink current can
be measured by setting the phase detector to a negative
polarity. The IF PLL currents can be measured in a similar
way. Note that the magnitude of the RF and IF PLL charge
pump currents are also controlled by the RF_CP and IF_CP
bits. Once the charge pump currents are known, the mismatch can be calculated as well. In order to measure leakage currents, the charge pump current is set to a TRI-STATE
mode by enabling the counter reset bits. This is RF_RST for
the RF PLL and IF_RST for the IF PLL.
21
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LMX2364
Input Impedance
20050676
The above block diagram shows the test procedure measuring the input impedance for the LMX2364. This applies to the
FinRF, FinIF, OSCinRF, and OSCinIF pins. The input impedance of the CSP and the TSSOP package should always be
assumed to be different, until proven otherwise. The basic
test procedure is to calibrate the network analyzer, ensure
that the part is powered up, and then measure the input
impedance.
The network analyzer can be calibrated by using either
calibration standards or by soldering resistors directly to the
evaluation board. An open can be implemented by putting no
resistor, a short can be implemented by using a 0 ohm
resistor, and a short can be implemented by using two 100
ohm resistors in parallel. Note that no DC blocking capacitor
is used for this test procedure. This is done with the PLL
removed from the PCB. This requires the use of a clamp
down fixture that may not always be generally available. If no
clamp down fixture is available, then this procedure can be
done by calibrating up to the point where the DC blocking
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capacitor usually is, and then adding a 0 ohm resistor back
for the actual measurement.
Once that the network analyzer is calibrated, it is necessary
to ensure that the PLL is powered up. This can be done by
toggling the power down bits (RF_PD and IF_PD) and observing that the current consumption indeed increases when
the bit is disabled. Sometimes it may be necessary to apply
a signal to the OSCinIF pin in order to program the part. If
this is necessary, disconnect the signal once it is established
that the part is powered up.
It is useful to know the input impedance of the PLL for the
purposes of debugging RF problems and designing matching networks. Another use of knowing this parameter is make
the trace width on the PCB such that the input impedance of
this trace matches the real part of the input impedance of the
PLL frequency of operation. In general, it is good practice to
keep trace lengths short and make designs that are relatively
resistant to variations in the input impedance of the PLL.
22
The LMX2364 RF PLL is a capable of operating as both a
Fractional N synthesizer and an Integer N synthesizer. Operating in Fractional mode is likely to yield the best phase
noise, but Integer mode often yields the lowest spur levels.
The operating mode is determined by the RF_OM[1:0] word.
It is possible to cause this PLL to behave as an integer PLL
in fractional mode by setting the fractional numerator,
RF_FN, to zero and disabling the fractional compensation
that is controlled by the FE bit. However, by actually setting
the part to Integer mode allows the range of the counters to
be extended.
1.0 GENERAL
The basic phase-lock-loop (PLL) configuration consists of a
high-stability crystal reference oscillator, a frequency synthesizer such as the National Semiconductor LMX2364, a voltage controlled oscillator (VCO), and a passive loop filter. The
frequency synthesizer includes a phase detector, charge
pump, and programmable frequency dividers. These dividers are the reference [R] and feedback [N] frequency dividers. The VCO frequency is established by dividing the crystal
reference signal down via the R counter to obtain a frequency in order to establish the comparison frequency. This
comparison frequency, fCOMP, is input to the phase detector,
which compares this signal to another signal, fN, the feedback signal. fN is the result of dividing the VCO frequency
down by way of the N counter and fractional circuitry. The
phase/frequency detector’s charge pump outputs a current
into the loop filter, which is then converted into the VCO’s
control voltage. The phase/frequency comparator’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 VCO’s frequency will be N+F times that of the comparison frequency, where N is the integer component of the
divide ratio and F is the fractional component. Fractional
synthesis allows the phase detector frequency to be increased while maintaining the same frequency step size for
channel selection. The division value N is thereby reduced
giving a lower phase noise referred to the phase detector
input, and the comparison frequency is increased allowing
faster switching times.
1.2 POWER DOWN
The LMX2364 can be powered down via the two software
bits and the two enable pins. The RF PLL is only powered up
when the ENRF pin is high and the RF_PD bit ( R4[23] ) is
low. In a similar manner, the IF PLL is powered up only when
the ENIF pin is high and the IF_PD bit ( R1[23] ) is low.
1.3 OSCILLATOR
The OSCinRF and OSCinIFpins are used to drive the R
dividers for the RF and IF PLLs. In the case that the OSC Bit
( R6[7] ) is set to 0, the RF R counter is driven by the
OSCinRF pin and the IF R counter is driven independently of
this by the OSCinIF pin. In the case that both R counters are
to be driven with the same frequency, this bit needs to be set
to one. This PLL does not support the use of a crystal in any
mode.
23
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LMX2364
1.1 OPERATING MODES
Functional Description
LMX2364
Programming Description
2.0 INPUT DATA REGISTER
The 24-bit input data register is loaded through the MICROWIRE Interface. The input data register is used to program the control
registers. The data format of the 24-bit data register is shown below. The control bits (CTL[2:0]) decode the internal register
address and the data bits (DATA[21:0]) are used to program various control words for the synthesizer. On the rising edge of LE,
data stored in the input date register is loaded into one of the 8 appropriate latches (selected by control bits). Data is shifted in
MSB first
MSB
LSB
DATA [21:0]
CTL[2:0]
23
3 2
0
2.1 REGISTER LOCATION TRUTH TABLE
The control bits CTL[2:0] decode the internal register address. The table below shows how the control bits are mapped to the
target control register.
CTL[2:0]
Target Control Register
0
R0
1
R1
2
R2
3
R3
4
R4
5
R5
6
R6
7
This address is invalid.
2.2 CONTROL REGISTER CONTENT MAP
The control register content map describes how the bits within each control register are allocated to specific control functions. The
bits that are marked “0” should be programmed as such to insure proper device operation. It is important to note that some control
words are dual mapped and take one a different control function depending on the operating mode of the device.
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
2
1
0
C2
C1
C0
0
0
0
0
0
1
0
1
0
RF_FD[6:0]
0
1
1
RF_FN[6:0]
1
0
0
1
0
1
1
1
0
DATA[20:0]
R0
0
0
0
IF_
RST
R1
IF_
PD
0
0
0
0
0
0
0
R2
R3
RF_ RF_ RF_
RST P CPP
R4
RF_
PD
R5
0
R6
0
IF_
CP
IF_
CPP
IF_R[14:0]
IF_N[16:0]
0
0
0
IF_TOC[13:0]
RF_
CP[1:0]
RF_R[8:0]
RF_N[12:0]
RF_
CSR[1:0]
0
www.national.com
0
RF_
OM[1:0]
0
0
RF_
CPF[1:0]
0
0
RF_TOC[13:0]
FE
0
0
0
0
24
0
0
0
PD_ OSC
M
MUX[3:0]
3
LMX2364
Programming Description
(Continued)
2.3 R0 REGISTER
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
DATA[20:0]
R0
0
0
0
IF_
RST
IF_
CP
IF_
CPP
2
1
0
C2
C1
C0
0
0
0
IF_R[14:0]
2.3.1 IF_R[14:0] — R Divider Ratio, IF Synthesizer
The R0 control word is used to configure the 15 Bit R Divider for the IF Synthesizer. Divide ratios ranging from 3 to 32,767 are
supported.
IF_R[14:0]
Divide
Ratio
14
13
12
11
10
9
8
7
6
5
4
3
2
1
0
3
0
0
0
0
0
0
0
0
0
0
0
0
0
1
1
4
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
•
32,767
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2.3.2 IF_CPP — Charge Pump Polarity, IF Synthesizer
This bit controls the polarity of phase detector for the IF synthesizer. It should be set to “1” when the IF VCO has positive tuning
gain, and “0” when the tuning gain is negative.
2.3.3 IF_CP — Charge Pump Gain, IF Synthesizer
This bit controls the charge pump gain for the IF Synthesizer. Set this bit to 0 for low gain mode (100 uA) and a 1 for high gain
mode (800 uA). When FastLock mode is enabled, the charge pump gain is controlled by the FastLock circuit.
2.3.4 IF_RST — Counter Reset, IF Synthesizer
The IF Counter Reset enable bit when activated (IF_RST = 1) allows the reset of both the IF N and R dividers and sets the IF
charge pump to a TRI-STATE condition ® . Upon powering up, the N counter resumes counting in "close" alignment with the R
counter. The maximum error is one prescaler cycle.
25
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LMX2364
Programming Description
(Continued)
2.4 R1 REGISTER
This register is used to configure the N divider for the IF synthesizer. A single word write to this register is all that is required to
power up and tune the synthesizer to the desired frequency.
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
DATA[20:0]
R1
IF_
PD
0
0
0
IF_N[16:0]
2
1
0
C2
C1
C0
0
0
1
2.4.1 IF_N[16:0] — N Divider Ratio,IF Synthesizer
The IF_N[16:0] word is used to setup up the N Divider Ratio for the IF synthesizer. The IF N counter is actually a combination of
an IF A counter, IF B counter, and an IF 8/9 prescaler. The relationship between IF_N, IF_B, and IF_A is shown below.
IF_N = 8 x IF_B + IF_A
Although the IF_N counter value can created by programming the IF_B and IF_A values, it is easier to simply convert the IF N
counter value into binary and program the entire IF_N[16:0] word in this manner. The fact that the IF N counter has a prescaler
is what puts restrictions on IF_N values less than 56.
IF_N[16:0]
IF_B[13:0]
16
15
14
13
12
0-23
11
10
IF_A[2:0]
9
8
7
6
5
4
3
2
1
0
0
Divide ratios of less than 24 are not allowed.
24-55
Legal divide ratios in this range are: 24-27, 32-36, 40-45, and 48-54.
56
0
0
0
0
0
0
0
0
0
0
0
1
1
1
0
0
57
0
0
0
0
0
0
0
0
0
0
0
1
1
1
0
0
1
...
...
...
...
...
...
...
...
...
...
...
...
...
...
...
...
...
...
131071
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
2.4.2 IF_PD — Power Down, IF Synthesizer
Activation of the IF Synthesizer power down bit results in the disabling of the respective N divider and de-biasing of its respective
Fin inputs (to a high impedance state). The respective R divider functionality also becomes disabled when the power down bit is
activated. The OSCinIF pin reverts to a high impedance state when both RF and IF power down bits are asserted. Power down
forces the respective charge pump and phase comparator logic to a TRI-STATE condition. The MICROWIRE control register
remains active and capable of loading and latching in data during all of the power down modes.
Both synchronous and asynchronous power down modes are supported. The power down mode bit R6[8] is used to select
between synchronous and asynchronous power down. The MICROWIRE control register remains active and capable of loading
and latching in data in either power down mode.
Synchronous Power Down Mode: The IF synthesizer can be synchronously powered down by first setting the power down
mode bit HIGH (R6[8] = 1) and then asserting its power down bit (R1[23] = 1). The power down function is gated by the charge
pump. Once the power down bit is loaded, the part will go into power down mode upon the completion of a charge pump pulse
event.
Asynchronous Power Down Mode: The IF synthesizer can be asynchronously powered down by first setting the power down
mode bit LOW (R6[8] = 0) and then asserting its power down bit (R1[23]] = 1). The power down function is NOT gated by the
charge pump. Once the power down bit is loaded, the part will go into power down mode immediately
www.national.com
26
LMX2364
Programming Description
(Continued)
2.5 R2 REGISTER
The R2 Register is used to setup the FastLock circuitry for the IF synthesizer.
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
DATA[20:0]
R2
0
0
0
0
0
0
0
IF_TOC[13:0]
2
1
0
C2
C1
C0
0
1
0
2.5.1 IF_TOC[13:0] — FastLock Timeout Counter, IF Synthesizer
The IF_TOC[13:0] word controls the operation of the IF FastLock circuitry as well as the function of the FLoutIF output pin. When
IF_TOC is set to a value between 0 and 3, the IF timeout counter is disabled and the FLoutIF pin operates as a general purpose
I/O pin. When IF_TOC is set to a value between 4 and 16383, the IF FastLock mode is enabled and FLoutIF is utilized as the IF
FastLock output pin. The value programmed into IF_TOC represents the number of phase comparison cycles that the IF
synthesizer will spend in the FastLock state.
IF_TOC[13:0]
FastLock Mode
FastLock Period
[CP Events]
0
Disabled
N/A
High Impedance
1
Disabled
N/A
Logic LOW State
2
Manual
N/A
Logic LOW State. Force IF Charge Pump to 800 µA
3
Disabled
3
Logic HIGH State
4
Enabled
4
FastLock
…
Enabled
…
FastLock
16,383
Enabled
16383
FastLock
27
FLoutIF Pin Functionality
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LMX2364
Programming Description
(Continued)
2.6 R3 REGISTER
The R3 register is used to setup the RF R Divider ratio as well as several other control functions related to the RF synthesizer.
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
DATA[20:0]
R3
RF_ RF_ RF_
RST P CPP
RF_
CP[1:0]
RF_R[8:0]
RF_FD[6:0]
2
1
0
C2
C1
C0
0
1
1
2.6.1 RF_FD[6:0] — Fractional Denominator, RF Synthesizer
In Fractional Mode, RF_FD[6:0] is used to specify the fractional denominator of the fractional part of the N counter value. Note
that in this mode, values below 32 are not supported. If a fractional denominator between 2 and 32 is desired, the same N counter
value can be achieved by multiplying the fractional numerator and denominator by some constant factor. For instance, 1/16 can
be expressed as 5/80.
In integer mode, the value represented by this bit multiplies both the RF_N and RF_R counter values. If both of these counter
sizes are sufficiently large, it is recommended to set this bit to one. If the counter sizes are too small, this bit can be used to extend
the counter range.
RF_FD
Value
RF_FD[6:0]
Integer Mode
Fractional Mode
[RF_OM = 0]
RF_OM = 1
0
128
128
1
1
Not Supported (Use Integer Mode Instead)
…
…
Not Supported ( Use a higher value )
32
32
32
33
33
33
34
34
34
…
…
…
127
127
127
Value
Fractional Mode
(RF_OM=1)
Integer Mode
(RF_OM=0)
R Divider Value
RF_R
RF_R x RF_FD
Complete N Divider Value
RF_N x RF_FN/RF_FD
RF_N x RF_FD + RF_FN
See R divider programming (section 2.6.2 ) and N divider programming (Section 2.7.2) for more detailed programming
information.
2.6.2 RF_R[8:0] — R Divider Ratio, RF Synthesizer
RF_R[8:0] is used to specify an integer value from 1 to 511 that is used in calculating the R divider ratio for the RF synthesizer.
In the case that the PLL is operating in fractional mode, the R counter value is simply the value represented by RF_R. However,
in integer mode, the R counter value is calculated by multiplying RF_R by the fractional denominator value.
R (Integer Mode) = RF_R x RF_FD
Since RF_R can take on integer values between 1 – 511 and RF_FD can take on integer values between 1 – 128, this value can
range from 1 - 65408, although prime values between 512 and 65,408 can not be realized.
www.national.com
RF_R[8:0]
RF_R
Value
0
Not Supported
1
1
…
…
511
511
28
(Continued)
2.6.3 RF_CP[1:0] — Charge Pump Gain, RF Synthesizer
The RF_CP word is used to control the charge pump gain for the RF synthesizer. Four different CP gains are supported ranging
from 1 to 16 mA. Note that when RF FastLock mode is enabled and the synthesizer is operating in the FastLock state, the charge
pump gain is controlled by the RF_CPF[1:0] control word. Higher charge pump currents yield slightly better phase noise, but lead
to larger loop filter capacitors and slightly higher current consumption in cases where the comparison frequency is very high.
RF_CP[1:0]
Charge Pump Current
0
1 mA
1
4 mA
2
8 mA
3
16 mA
2.6.4 RF_CPP — Phase Detector Polarity, RF Synthesizer
This bit controls the polarity of phase detector for the RF synthesizer. It should be set to one when the chosen RF VCO has
positive tuning gain, and zero when the tuning gain is negative.
2.6.5 RF_P — Prescaler, RF Synthesizer
The RF synthesizer utilizes a selectable quadruple modulus prescaler. RF_P selects between the 8/9/12/13 prescaler and the
16/17/20/21 prescaler as described in the table below.
RF_P[1:0]
Selected Prescaler
0
8 (8/9/12/13)
1
16 (16/17/20/21)
2.6.6 RF_RST — Counter Reset, RF Synthesizer
The RF Counter Reset enable bit when activated (RF_RST = 1) allows the reset of both the RF N and RF R dividers. Upon
powering up, the N counter resumes counting in "close" alignment with the R counter. The maximum error is one prescaler cycle.
29
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LMX2364
Programming Description
LMX2364
Programming Description
(Continued)
2.7 R4 REGISTER
This register is used to setup the N divider for the RF Synthesizer. A single word write to this register is all that is required to power
up and tune the RF synthesizer to the desired frequency.
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
DATA[20:0]
R4
RF_
PD
RF_N[12:0]
RF_FN[6:0]
2
1
0
C2
C1
C0
1
0
0
2.7.1 RF_FN — Fractional Numerator, RF Synthesizer
In the case that the PLL is operating in fractional mode (RF_OM=1), RF_FN[6:0] specifies the fractional numerator of the
complete N counter value of the RF PLL. In the case that the PLL is operating in integer mode (RF_OM=0), RF_FN adds to the
total value of the N counter.
Operating Mode
RF N Divider Value Calculation
Fractional Mode (RF_OM=1)
RF_N +RF_FN/RF_FD
Integer Mode (RF_OM=0)
RF_N x RF_FD + RF_FN
2.7.2 RF_N[12:0] — N Divider Ratio, RF Synthesizer
RF_N[12:0] specifies an integer value that is used in calculating the N divider ratio for the RF synthesizer. In the case the part is
operating in fractional mode, it value is the N divider ratio. In the case the part is operating in integer mode, this number is used
in conjunction with the RF_FD and RF_FN values to calculate the N divider value. The range of values supported is dependant
on the selected prescaler. When the 8/9/12/13 prescaler is selected, RF_N value can range from 40 to 4095. When the
16/17/20/21 prescaler is selected, the RF_N value can range from 80 to 8191. The following tables describe how to program a
specific value of RF_N for a given prescaler.
The RF_N value is actually created using a prescaler, C counter, B counter, and an A counter. If RF_P = 16, then the RF_N[12:0]
word is just the binary representation of the desired value. If RF_P = 8, then the case is similiar, except that the third LSB is
disregarded in all calculations. The relationship between RF_N, RF_P, RF_A, RF_B, and RF_C is shown below.
RF_N = RF_PxRF_C +4xRF_B + RF_A
RF_N[12:0] Programming with RF_P = 16
RF_N[12:0]
12
11
10
9
8
7
6
5
4
3
RF_C[8:0]
0–47
2
1
RF_B [1:0]
0
RF_A[1:0]
Values from 0–47 are not allowed.
Some of these N values are allowed, others are illegal divide ratios and not allowed.
48–79
Legal Divide Ratios in Fractional Mode:
Legal Divide Ratios in Integer Mode:
48–49, 52–53, 64–66, 68–70, 72–74, 76–78
All these values are legal in integer mode.
80
0
0
0
0
0
0
1
0
1
0
0
0
0
81
0
0
0
0
0
0
1
0
1
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
4
3
2
1
…
8191
RF_N[12:0] Programming with RF_P = 8
RF_N[12:0]
12
11
10
9
8
7
6
5
RF_C[8:0]
0–23
RF_B[1:0]
0
RF_A[1:0]
Values from 0–23 are not allowed.
Some of these N values are allowed, others are illegal divide ratios and not allowed.
24–39
Legal Divide Ratios in Fractional Mode:
Legal Divide Ratios in Integer Mode:
24–25, 28–29, 32–34, 36–38
All these values are legal in integer mode.
40
0
0
0
0
0
0
0
1
1
X
0
0
0
41
0
0
0
0
0
0
0
1
1
X
0
0
1
1
1
1
1
1
1
1
1
1
X
1
1
1
…
4095
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30
(Continued)
2.7.3 RF_PD — RF Synthesizer Power Down
Activation of the RF Synthesizer power down bit results in the disabling of the respective N divider and de-biasing of its respective
Fin inputs (to a high impedance state). The respective R divider functionality also becomes disabled when the power down bit is
activated. The OSCinRF pin reverts to a high impedance state when both RF and IF power down bits are asserted. Power down
forces the respective charge pump and phase comparator logic to a TRI-STATE condition. The MICROWIRE control register
remains active and capable of loading and latching in data during all of the power down modes.
Both synchronous and asynchronous power down modes are available with the LMX2364 in order to adapt to different types of
applications. The power down mode bit R6[8] is used to select between synchronous and asynchronous power down. The
MICROWIRE control register remains active and capable of loading and latching in data in either power down mode.
Synchronous Power down Mode: The RF synthesizer can be synchronously powered down by first setting the power down
mode bit HIGH (R6[8] = 1) and then asserting its power down bit (R4[23] = 1). The power down function is gated by the charge
pump. Once the power down bit is loaded, the part will go into power down mode upon the completion of a charge pump pulse
event.
Asynchronous Power down Mode: The RF synthesizer can be asynchronously powered down by first setting the power down
mode bit LOW (R6[8] = 0) and then asserting its power down bit (R4[23]] = 1). The power down function is NOT gated by the
charge pump. Once the power down bit is loaded, the part will go into power down mode immediately
31
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LMX2364
Programming Description
LMX2364
Programming Description
(Continued)
2.8 R5 REGISTER
The R5 Register is used to setup and control the FastLock circuitry for the RF synthesizer.
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
3
DATA[20:0]
R5
0
RF_
CSR[1:0]
RF_
OM[1:0]
RF_
CPF[1:0]
2
1
0
C2
C1
C0
1
0
1
RF_TOC[13:0]
2.8.1 RF_TOC[13:0] — FastLock Timeout Counter, RF Synthesizer
The RF_TOC[13:0] word controls the operation of the RF FastLock circuitry as well as the function of the FLoutRF output pin.
When RF_TOC is set to a value between 0 and 3, the RF timeout counter is disabled and the FLoutRF pin operates as a general
purpose I/O pin. When RF_TOC is set to a value between 4 and 16383, the RF FastLock mode is enabled and FLoutRF is utilized
as the RF FastLock output pin. The value programmed into RF_TOC represents the number of phase comparison cycles that the
RF synthesizer will spend in the FastLock state.
RF_TOC[13:0]
FastLock Mode
FastLock Period
[CP Events]
0
Disabled
N/A
High Impedance
1
Disabled
N/A
Logic LOW State
2
Manual
N/A
Logic LOW State. Force RF Change Pump to 16 mA
3
Disabled
3
Logic HIGH State
4
Enabled
4
FastLock
…
Enabled
…
FastLock
16,383
Enabled
16383
FastLock
FLoutRF Pin Functionality
2.8.2 RF_CPF[1:0] — FastLock Charge Pump Gain, RF Synthesizer
The RF_CPF[1:0] word is used to control the charge pump gain for the RF synthesizer when FastLock is enabled and engaged.
Four different CP gains are supported ranging from 1 to 16 mA. Note that when RF FastLock mode is disengaged or disabled the
charge pump gain is controlled by RF_CP[1:0].
RF_CPF[1:0]
Charge Pump Current
0
1 mA
1
4 mA
2
8 mA
3
16 mA
2.8.3 RF_OM[1:0] — RF Synthesizer Operating Mode
RF_OM[1:0] controls the operating mode of the RF synthesizer. The various operating modes are described below:
RF Synthesizer Operating Mode Descriptions
RF_OM
FE < R6[16] >
Operating Mode
0
0
Integer
1
1
Fractional
RF synthesizer always operates as a Fractional N PLL
2
X
Reserved
Do Not use this mode
3
X
Reserved
Do Not use this mode.
Operating Mode Description
RF synthesizer always operates as an Integer N PLL
Note that the Fractional Enable Bit, FE (R6[16]) needs to be set appropriately. Enabling the fractional compensation in Integer
mode always degrades performance. It is generally recommended to enable it in fractional mode, although there may be some
rare exceptions that it may be set to 0.
2.8.4 RF_CSR[1:0] — Cycle Slip Reduction Control, RF Synthesizer
RF_CSR[1:0] controls the operation of the cycle slip reduction circuitry. This circuit can be used eliminate the occurrence of phase
detector cycle slips when operating in Fractional Mode (RF_OM = 1). When operating in integer mode,the cycle slip reduction
circuitry should be disabled by setting RF_CSR = 0.
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RF_CSR
CSR State
Sample Rate Reduction Factor
0
Disabled
N/A
1
Enabled
1/2
2
Enabled
1/4
3
Enabled
1/8
32
LMX2364
Programming Description
(Continued)
2.9 R6 REGISTER
Reg
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
DATA[20:0]
R6
0
0
0
0
0
0
0
FE
0
0
0
0
0
0
0
PD_ OSC
M
MUX[3:0]
3
2
1
0
C2
C1
C0
1
1
0
2.9.1 MUX[3:0] — Coltrol Word for the Ftest/LD Pin
The MUX[3:0] control word is used to determine the function of the Ftest/LD output pin. The pin can be setup as a generalpurpose CMOS TRI-STATE I/O pin, a digital filtered lock detect pin, an analog lock detect pin (push-pull or open drain output), or
used to view the output of the various R & N dividers.
MUX[3:0]
Ftest/LD Output Pin Function
Output Type
0
0
0
0
Disabled
High Impedance
0
0
0
1
General Purpose I/O. Logic HIGH Output
0
0
1
0
General Purpose I/O. Logic LOW Output
0
0
1
1
RF & IF Analog Lock Detect (Width of
narrow low pulses determines lock)
Open-Drain
0
1
0
0
RF Analog Lock Detect (Width of narrow
low pulses determines lock)
Open-Drain
0
1
0
1
IF Analog Lock Detect (Width of narrow
low pulses determines lock)
Open-Drain
0
1
1
0
RF & IF Digital Lock Detect (High = Lock)
Push-Pull
0
1
1
1
RF Digital Lock Detect (High = Lock)
Push-Pull
1
0
0
0
IF Digital Lock Detect (High = Lock)
Push-Pull
1
0
0
1
RF & IF Analog Lock Detect (Width of
narrow low pulses determines lock)
Push-Pull
1
0
1
0
RF Analog Lock Detect (Width of narrow
low pulses determines lock)
Push-Pull
1
0
1
1
IF Analog Lock Detect (Width of narrow
low pulses determines lock)
Push-Pull
1
1
0
0
IF R Divider/2 (Output is divided by 2 to
simplify testing)
Push-Pull
1
1
0
1
IF N Divider/2 (Output is divided by 2 to
simplify testing)
Push-Pull
1
1
1
0
RF R Divider/2 (Output is divided by 2 to
simplify testing)
Push-Pull
1
1
1
1
RF N Divider/2 (Output is divided by 2 to
simplify testing)
Push-Pull
Push-Pull
Push-Pull
2.9.2 OSC — Single Resonator Mode
The OSC bit selects whether the oscillator input pins OSCinIF and OSCinRF drive the IF and RF R dividers separately or by a
common input signal path. When OSC is set to 0, the OSCinIF pin drives the IF R divider while the OSCinRF pin drives the RF
R divider. When the OSC bit is set to “1” the OSCinIF pin drives both the RF R and IF R counters. Note that setting the OSC mode
to “1” does not allow the use of a crystal. This part does not include the inverter for use in construction of a crystal oscillator.
2.9.3 PD_M — Power Down Mode
This bit determines if a power down event for either synthesizer will be handled synchronously or asynchronously with respect to
a charge pump event. Synchronous powerdown means that the PLL does not power down until the charge pump turns off.
Asynchronous powerdown means that the PLL powers down, regardless of the charge pump state. When set to one,
synchronous mode is enabled. When set to 0, asynchronous mode is enabled. The setting of this bit applies to both the RF & IF
synthesizers.
2.9.4 FE — Fractional Compensation Enable
For integer mode (RF_OM = 0 ) mode, this bit should always be set to 0. For fractional mode (RF_OM = 1), this bit should be set
to 1 for the best fractional spurs. However, there may be applications using fractional mode where it would be beneficial to set
this bit to 0. Disabling this bit will drastically degrade the fractional spurs, but will also result in a small improvement in phase
noise, which may be practical for some applications.
Fractional Mode
FE
Fractional
Compensation
Circuitry
Integer
Mode
0
Disabled
1
Enabled
Approximate Spur
Improvement
Approximate Phase
Noise
Degradation
Default State
0 dB
0 dB
Illegal State
20 dB
7 dB
33
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LMX2364
15nS RC delay for 5 consecutive reference cycles. Once in
lock (Lock = HIGH), the RC delay is changed to approximately 30nS. To exit the locked state (Lock = LOW), the
phase error must become greater than the 30nS RC delay.
When the PLL is in the power down mode, Lock is forced
LOW. A flow chart of the digital filter is shown below.
Supplemental Information
3.0 USE OF THE DIGITAL LOCK DETECT FUNCTION
The Lock Detect Digital Filter compares the difference between the phase of the inputs of the phase detector to a RC
generated delay of approximately 15nS. To enter the locked
state (Lock = HIGH) the phase error must be less than the
20050604
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34
Complimentary High Frequency Pins, FinRF* and FinIF*:
These outputs may be used to drive the PLL differentially,
but it is very common to drive the PLL in a single ended
fashion. These capacitors should be chosen such that the
impedance, including the ESR of the capacitor, is as close to
an AC short as possible at the operating frequency of the
PLL. 100 pF is a typical value.
(Continued)
3.1 PCB LAYOUT CONSIDERATIONS
Power Supply Pins: For these pins, it is recommended that
these be filtered by taking a series 18 ohm resistor and then
placing two capacitors shunt to ground, thus creating a
lowpass filter. Although theoretically, it makes sense to make
these capacitors as large as possible, the ESR ( Equivalent
Series Resistance ) is greater for larger capacitors. It is
therefore recommended to provide two capacitors of very
different sizes for the best filtering. 0.1 uF and 100 pF are
typical values. The charge pump supply pins in particular are
vulnerable to power supply noise.
High Frequency Input Pins, FinRF and FinIF: The signal
path from the VCO to the PLL is sensitive to matching and
layout, therefore creating unique challenges fro board layout. It is generally recommended that the VCO output go
through a resistive pad and then through a DC blocking
capacitor before it gets to these high frequency input pins. If
the trace length is sufficiently short ( < 1/10th of a wavelength ), then the pad may not be necessary, however, a
series resistor of about 39 ohms is still recommended to
isolate the PLL from the VCO. The DC blocking capacitor
should be chosen at least to be 100 pF. It may turn out that
the frequency in this trace is above the self-resonant frequency of the capacitor, but since the input impedance of the
PLL tends to be capacitive, it actually be a benefit to exceed
the self-resonant frequency. The pad and the DC blocking
capacitor should be placed as close to the PLL as possible
3.2 FASTLOCK AND CYCLE SLIP REDUCTION
CIRCUITRY OPERATION
The LMX2364 has enhanced features for FastLock operation. When the PLL is switching frequencies, the charge
pump current and comparison frequencies may be adjusted.
The purpose of increasing the charge pump current is to
increase the loop bandwidth. The purpose of reducing the
comparison frequency is to combat cycle slipping. If these
two parameters are not changed by the same ratio, then it is
necessary to switch in a resistor in order to keep the loop
filter optimized. Furthermore, it may be difficult in this case to
keep loop filters of higher than second order well optimized
during FastLock in these cases. The timeout counter controls how long the change in charge pump current and/or
comparison frequency is active. One also needs to realize
that there is a frequency glitch that is caused when any sort
of FastLock or Cycle Slip Reduction is disengaged. This
frequency glitch is application specific. In this case the table
below shows all the possible permutations for using the
FastLock and cycle slip reduction circuitry.
Keep Comparison Frequency
the Same
Increase Charge Pump
Current
Keep Charge Pump Current
the Same
Decrease Charge Pump
Current
Decrease Comparison Frequency
(RF Side Only)
Classical Fastlock
This mode allows the loop
bandwidth to be increased
during FastLock and then
switched back to normal after
FastLock is disengaged.
CSR/Fastlock Combination
This is the recommended way to use CSR.
If the charge pump gain is used to balance
the change in loop gain due to the lower
comparision frequency, no fastlock resistor
is necessary.
Operation Without Fastlock
This mode is essentially not
using fastlock at all.
CSR Only
In general, this mode is not recommended,
but it may be practical in some rare
situations.
Illegal Mode
This mode degrades performance and should never be used.
Note: If the charge pump current and cycle slip reduction
circuitry are engaged in the same proportion, then it is not
necessary to switch in a FastLock resistor and the loop filter
will be optimized for both normal mode and FastLocking
mode. For third and fourth order filters which have problems
with cycle slipping, this may prove to be the optimal choice of
settings.
35
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LMX2364
Supplemental Information
LMX2364
Supplemental Information
When K is greater than one, is necessary to switch a FastLock resistor, R2’, in parallel with R2 in order to keep the
loop filter optimized and maintain the same phase margin.
After the PLL has achieved a frequency that is sufficiently
close to the desired frequency, the resistor R2’ is disengaged
and the charge pump current is and comparison frequency
are returned to normal. Of special concern is the glitch that is
caused when the resistor R2’ is disengaged. This glitch can
take up a significant portion of the lock time. The LMX2364
has enhanced switching circuitry to minimize this glitch and
therefore improve the lock time.
(Continued)
3.3 DETERMINING THE THEORETICAL LOCK TIME
IMPROVEMENT AND FASTLOCK RESISTOR, R2
The loop bandwidth multiplier, K, is necessary in order to
determine the theoretical impact of FastLock/CSR on the
loop bandwidth and also which resistor should be switched
in parallel with the loop filter resistor R2. K = K_Kphi x
K_Fcomp where K is the loop gain multiplier K_Kphi and
K_Fcomp are the ratio of the FastLock currents and comparison frequencies to their steady state conditions. Note
that this should always be greater than or equal to one.
K_Fcomp is the ratio of the FastLock comparison frequency
to the steady state comparison frequency. If this ratio is less
than one, this implies that the CSR is being used.
20050640
The change in loop bandwidth is dependent upon the loop
gain multiplier, K. The theoretical improvement in lock time is
given below, but the actual improvement will be less than this
due to the glitch that is caused by disengaging FastLock.
The theoretical improvement is given to show an upper
bound on what improvement is possible with FastLock. In
the case that K < 1, this implies the CSR is being engaged
and that the theoretical lock time will be degraded. However,
since this mode reduces or eliminates cycle slipping, the
actual lock time may be better in cases where the loop
bandwidth is small relative to the comparison frequency.
Realize that the theoretical lock time multiplier does not
account for the FastLock/CSR disengagement glitch, which
is most severe for larger values of K.
Loop Gain Multiplier,
K
FastLock Loop
Bandwidth/Steady
State Loop
R2’ Value
Theoretical Lock
Time Multiplier
1:8*
0.35
open
x 2.828
1:4*
0.50
open
x 2.000
1:2*
0.71
open
x 1.414
1:1
1.00
open
x 1.000
2:1
1.41
R2/0.41
x 0.707
4:1
2.00
R2
x 0.500
8:1
2.83
R2/1.83
x 0.354
16:1
4.00
R2/3.00
x 0.250
K:1
1/
* These modes of operation are generally not recommended
detector. This can be reduced by increasing the loop bandwidth during frequency aquisition, decreasing the comparison frequency during frequency acquisition, or some combination of the these. If increasing the loop bandwidth during
frequency acquisition is not sufficient to reduce cycle slipping, the LMX2364 also has a routine to decrease the comparison frequency.
3.4 USING FASTLOCK AND CSR TO AVOID CYCLE
SLIPPING
In the case that the comparison frequency is very large ( ie.
70 x ) of the loop bandwidth, cycle slipping may occur when
an instantaneous phase error is presented to the phase
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36
FastLock charge pump current (RF_CPF[1:0]), and the
Cycle Slip Reduction Factor CSR.
(Continued)
3.5 RF PLL FASTLOCK REFERENCE TABLE
The table below shows most of the trade offs involved in
choosing a steady-state charge pump current (RF_CP), the
Parameter
Advantages to Choosing Smaller
RF_CP
1. Allows capacitors in loop filter to be smaller
values making it easier to find physically
smaller components and components with
better dielectric properties.
Advantages to Choosing Larger
Phase noise, especially within the loop
bandwidth of the system will be slightly worse
for lower charge pump currents. If the charge
pump gain is at least 4 mA, most of the
2. Allows a larger loop bandwidth multiplier for phase noise benefit will be realized.
FastLock, or a higher cycle slip reduction
factor.
RF_CPF
The only reason not to always choose this to This allows the maximum possible benefit for
16 mA is to make it such that no FastLock
FastLock.
resistor is required for FastLock. For 3rd and
4th order filters, it is not possible to keep the
filter perfectly optimized by simply switching in
a resistor for FastLock.
RF_CSR
Do not choose this any larger than necessary This will eliminate cycle slips better.
to eliminate cycle slipping. Keeping this small
allows a larger loop bandwidth multiplier for
FastLock.
3.6 CAPACITOR DIELECTRIC CONSIDERATIONS
The LMX2364 has a high fractional modulus and high
charge pump gain for the lowest possible phase noise. One
consideration is that the reduced N value and higher charge
pump may cause the capacitors in the loop filter to become
larger in value. For larger capacitor values, it is common to
have a trade-off between capacitor dielectric quality and
physical size. Using film capacitors or NP0/CG0 capacitors
yields the best possible lock times, where as using X7R or
Z5R capacitors can increase lock time by 0 – 500%. In
general, designs with higher comparison frequencies tend to
be less succeptible to degradations in lock time due to
capacitor dielectric effects. Capacitor dielectrics have very
little impact on phase noise or spurs. Although the use of
lesser quality dielectric capacitors may be unavoidable in
many circumstances, allowing a larger footprint for the loop
filter capacitors, using a lower charge pump current, and
reducing the fractional modulus are all ways to reduce capacitor values.
37
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LMX2364
Supplemental Information
LMX2364
Physical Dimensions
inches (millimeters) unless otherwise noted
Thin Shrink Small Outline (TSSOP) Package
Order Number LMX2364TM (Rail)
Order Number LMX2364TMX (Tape and Reel)
NS Package Number MTC24
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38
inches (millimeters) unless otherwise noted (Continued)
Ultra Thin Chip Scale Package (SLE)
For Tape and Reel (2500 Units per Reel)
Order Number LMX2364SLEX
NS Package Number SLE24A
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LMX2364 2.6 GHz PLLatinum Fractional RF Frequency Synthesizer with 850 MHz Integer-N IF
Frequency Synthesizer
Physical Dimensions