NSC LMX2531LQ1910E

LMX2531
High Performance Frequency Synthesizer System with
Integrated VCO
General Description
Features
The LMX2531 is a low power, high performance frequency
synthesizer system which includes a fully integrated deltasigma PLL and VCO with fully integrated tank circuit. The third
and fourth poles are also integrated and also adjustable. Also
included are integrated ultra-low noise and high precision
LDOs for the PLL and VCO which give higher supply noise
immunity and also more consistent performance. When combined with a high quality reference oscillator, the LMX2531
generates very stable, low noise local oscillator signals for up
and down conversion in wireless communication devices.
The LMX2531 is a monolithic integrated circuit, fabricated in
an advanced BiCMOS process. There are several different
versions of this product in order to accomdate different frequency bands.
Device programming is facilitated using a three-wire
MICROWIRE Interface that can operate down to 1.8 volts.
Supply voltage range is 2.8 to 3.2 Volts. The LMX2531 is
available in a 36 pin 6x6x0.8 mm Lead-Free Leadless Leadframe Package (LLP).
■ Multiple Frequency Options Available
Target Applications
— See Selection Guide Below
— Frequencies from: 765 MHz - 2790 MHz
■ PLL Features
— Fractional-N Delta Sigma Modulator Order
programmable up to 4th order
— FastLock/Cycle Slip Reduction with Timeout Counter
— Partially integrated, adjustable Loop Filter
— Very low phase noise and spurs
■ VCO Features
— Integrated tank inductor
— Low phase noise
■ Other Features
— 2.8 V to 3.2 V Operation
— Low Power-Down Current
— 1.8V MICROWIRE Support
— Package: 36 Lead LLP
Part
Low Band
High Band
■ 3G Cellular Base Stations (WCDMA, TD-
LMX2531LQ1570E
765 - 818 MHz
1530 - 1636 MHz
LMX2531LQ1650E
795 - 850 MHz
1590 - 1700 MHz
■
LMX2531LQ1700E
831 - 885 MHz
1662 - 1770 MHz
LMX2531LQ1742
880 - 933 MHz
1760 - 1866 MHz
LMX2531LQ1778E
863 - 920 MHz
1726 - 1840 MHz
LMX2531LQ1910E
917 - 1014 MHz
1834 - 2028 MHz
LMX2531LQ2080E
952 - 1137 MHz
1904 - 2274 MHz
■
■
■
■
■
■
■
■
SCDMA,CDMA2000)
2G Cellular Base Stations (GSM/GPRS, EDGE,
CDMA1xRTT)
Wireless LAN
Broadband Wireless Access
Satellite Communications
Wireless Radio
Automotive
CATV Equipment
Instrumentation and Test Equipment
RFID Readers
© 2007 National Semiconductor Corporation
201011
LMX2531LQ2265E 1089 - 1200 MHz 2178 - 2400 MHz
LMX2531LQ2570E 1168 - 1395 MHz 2336 - 2790 MHz
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LMX2531 High Performance Frequency Synthesizer System with Integrated VCO
January 2007
LMX2531
Functional Block Diagram
20101101
Connection Diagram
36-Pin LLP (LQ) Package
20101102
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2
LMX2531
Pin Descriptions
Pin #
Pin Name
I/O
Description
1
VccDIG
-
Power Supply for digital LDO circuitry. Input may range from 2.8 - 3.2 V. Bypass capacitors should be
placed as close as possible to this pin and ground.
3
GND
-
Ground
2,4,5,7,
12, 13,
29, 35
NC
-
No Connect.
6
VregBUF
-
Internally regulated voltage for the VCO buffer circuitry. Connect to ground with a capacitor.
8
DATA
I
MICROWIRE serial data input. High impedance CMOS input. This pin must not exceed 2.75V. Data is
clocked in MSB first. The last bits clocked in form the control or register select bits.
9
CLK
I
MICROWIRE clock input. High impedance CMOS input. This pin must not exceed 2.75V. Data is clocked
into the shift register on the rising edge.
10
LE
I
MICROWIRE Latch Enable input. High impedance CMOS input. This pin must not exceed 2.75V. Data
stored in the shift register is loaded into the selected latch register when LE goes HIGH.
11
CE
I
Chip Enable Input. High impedance CMOS input. This pin must not exceed 2.75V. When CE is brought
high the LMX2531 is powered up corresponding to the internal power control bits. It is necessary to
reprogram the R0 register to get the part to re-lock.
14, 15
NC
-
No Connect. Do NOT ground.
16
VccVCO
-
Power Supply for VCO regulator circuitry. Input may range from 2.8 - 3.2 V. Bypass capacitors should
be placed as close as possible to this pin and ground.
17
VregVCO
-
Internally regulated voltage for VCO circuitry. Not intended to drive an external load. Connect to ground
with a capacitor and some series resistance.
18
VrefVCO
-
Internal reference voltage for VCO LDO. Not intended to drive an external load. Connect to ground with
a capacitor.
19
GND
-
Ground for the VCO circuitry.
20
GND
-
Ground for the VCO Output Buffer circuitry.
21
Fout
O
Buffered RF Output for the VCO.
22
VccBUF
-
Power Supply for the VCO Buffer circuitry. Input may range from 2.8 - 3.2 V. Bypass capacitors should
be placed as close as possible to this pin and ground.
23
Vtune
I
Tuning voltage input for the VCO. For connection to the CPout Pin through an external passive loop
filter.
24
CPout
O
Charge pump output for PLL. For connection to Vtune through an external passive loop filter.
25
FLout
O
An open drain NMOS output which is used for FastLock or a general purpose output.
26
VregPLL1
-
Internally regulated voltage for PLL charge pump. Not intended to drive an external load. Connect to
ground with a capacitor.
27
VccPLL
-
Power Supply for the PLL. Input may range from 2.8 - 3.2 V. Bypass capacitors should be placed as
close as possible to this pin and ground.
28
VregPLL2
-
Internally regulated voltage for RF digital circuitry. Not intended to drive an external load. Connect to
ground with a capacitor.
30
Ftest/LD
O
Multiplexed CMOS output. Typically used to monitor PLL lock condition.
31
OSCin
I
Oscillator input.
32
OSCin*
I
Oscillator complimentary input. When a single ended source is used, then a bypass capacitor should be
placed as close as possible to this pin and be connected to ground.
33
Test
O
This pin if for test purposes and should be grounded for normal operation.
34
GND
-
Ground
36
VregDIG
-
Internally regulated voltage for LDO digital circuitry.
3
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LMX2531
Connection Diagram
20101111
Pin(s)
Application Information
VccDIG
Because the LMX2531 contains internal regulators, the power supply noise rejection is very good and capacitors at
VccVCO
this pin are not critical. If desired, capacitors can be placed at these pins to improve the noise rejection. Recommended
VccBUF
values are from open to 1 μF.
VccPLL
VregDIG There is not really any reason to use any other values than the recommended values.
VrefVCO
If the VregVCO capacitor is changed, it is recommended to keep this capacitor between 1/100 and 1/1000 of the value
of the VregVCO capacitor.
Because this pin is the output of a regulator, there are be stability concerns if there is not sufficient series resistance.
For ceramic capacitors the ESR (Equivalent Series Resistance) is too low, and it recommended that a series
VregVCO
resistance of 1 - 3.3Ω is necessary. If there is insufficient ESR, then there may be degradation in the phase noise,
especially in the 100 - 300 kHz offset. Recommended values are from 1 μF to 10 μF.
The choice of the capacitor value at this pin involves a trade-off between integer spurs and phase noise in the 100 VregPLL1 300 kHz offset range. If too much series resistance is at this pin, the spurs at far offset will be severely degraded. If
VregPLL2 there is too little, the phase noise may be degraded. A 470 nF capacitor in series with 220 mΩ provides optimal spurs
with a minimal degradation in phase noise, although these optimal values may be design specific.
CLK
DATA
LE
Since the maximum voltage on these pins is less than the minimum Vcc voltage, level shifting may be required, if the
output voltage of the microcontroller is too high. This can be accomplished with a resistive divider.
CE
As with the CLK, DATA, and LE pins, level shifting may be required if the output voltage of the microcontroller is too
high. A resistive divider is or a series diode are two ways to accomplish this. The diode has the advantage that no
current flows through it when the chip is powered down.
Ftest/LD It is an option to use the lock detect information from this pin.
Fout
This is the high frequency output. This needs to be AC coupled, and matching may also be required. The value of the
DC blocking capacitor may be changed, depending on the output frequency.
CPout
Vtune
In most cases, it is sufficient to short these together. C1_LF, C2_LF, and R2_LF are used in conjunction with the
internal loop filter to make a fourth order loop filter. However, the user always has the option of adding additional
poles.
R2pLF
This is the fastlock resistor, which can be useful in many cases, since the spurs are often better with low charge pump
currents, and the internal loop filter can be adjusted during fastlock.
OSCin
This is the crystal oscillator input pin. It needs to be AC coupled.
OSCin*
If the device is being driven single-ended, this pin needs to be shunted to ground with a capacitor.
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4
If Military/Aerospace specified devices are required, please contact the National Semiconductor Sales Office/ Distributors
for availability and specifications.
Parameter
Power Supply Voltage
Symbol
VCC
(VccDIG, VccVCO,
VccBUF, VccPLL)
All other pins (Except
Ground)
Ratings
Units
-0.3 to 3.5
V
-0.3 to 3.0
Storage Temperature
Range
TSTG
-65 to 150
°C
Lead Temperature (solder 4 sec.)
TL
+ 260
°C
Recommended Operating Conditions
Parameter
Power Supply Voltage
(VccDig, VccVCO, VccBUF)
Serial Interface and Power Control
Voltage
Ambient Temperature
(Note 3)
Symbol
Min
Typ
Max
Units
Vcc
2.8
3.0
3.2
V
Vi
0
2.75
V
TA
-40
+85
°C
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Recommended Operating Conditions 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 to the test conditions listed.
5
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LMX2531
Absolute Maximum Ratings (Note 1)
LMX2531
Electrical Characteristics
Symbol
(VCC = 3.0 V, -40°C ≤ TA ≤ 85 °C; except as specified.)
Parameter
Conditions
Min
Typ
Max
Units
Current Consumption
ICC
ICCPD
Power Supply Current
(All Parts Except
LMX2531LQ2265E,
LMX2531LQ2570E)
Divider Disabled
34
41
Divider Enabled
37
46
Power Supply Current
(LMX2351LQ2265E,
LMX2531LQ2570E)
Divider Disabled
38
44
Divider Enabled
41
49
CE = 0 V, Part Initialized
7
Power Down Current
mA
µA
Oscillator
IIHOSC
Oscillator Input High Current
VIH = 2.75 V
IILOSC
Oscillator Input Low Current
VIL = 0
fOSCin
Frequency Range
vOSCin
Oscillator Sensitivity
100
µA
5
80
MHz
0.5
2.0
Vpp
32
MHz
-100
µA
PLL
fCOMP
Phase Detector Frequency
Charge Pump
Output Current Magnitude
ICPout
ICP = 0
90
µA
ICP = 1
180
µA
µA
ICP = 3
360
ICP = 15
1440
µA
ICPoutTRI
CP TRI-STATE Current
0.4 V < VCPout < 2.0 V
2
10
nA
ICPoutMM
Charge Pump
Sink vs. Source Mismatch
VCPout = 1.2 V
TA = 25°C
2
8
%
ICPoutV
Charge Pump
Current vs. CP Voltage Variation
0.4 V < VCPout < 2.0 V
TA = 25°C
4
%
ICPoutT
CP Current vs. Temperature
Variation
VCPout = 1.2 V
8
%
ICP = 1X Charge Pump Gain
4 kHz Offset
-202
LN(f)
Normalized Phase Noise
Contribution
(Note 2)
ICP = 16X Charge Pump Gain
4 kHz Offset
-212
dBc/Hz
VCO Frequencies
fFout
Operating Frequency Range
(All options have a frequency divider,
this applies before the divider. The
frequency after the divider is half of
what is shown)
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LMX2531LQ1570E
1530
1636
LMX2531LQ1650E
1590
1700
LMX2531LQ1700E
1662
1770
LMX2531LQ1742
1760
1866
LMX2531LQ1778E
1726
1840
LMX2531LQ1910E
1834
2028
LMX2531LQ2080E
1904
2274
LMX2531LQ2265E
2178
2400
LMX2531LQ2570E
2336
2790
6
MHz
Parameter
Conditions
Min
Typ
Max
Units
Other VCO Specifications
ΔTCL
Maximum Allowable Temperature
Drift for Continuous Lock
(Note 3)
LMX2531LQ1742
65
LMX2531LQ1570E, LMX2531LQ1650E
90
LMX2531LQ1700E, LMX2531LQ1778E,
LMX2531LQ1910E, LMX2531LQ2080E,
LMX2531LQ2265E,LMX2531LQ2570E
125
LMX2531LQ1570E
2.0
4.5
8.0
LMX2531LQ1650E
2.0
4.5
8.0
LMX2531LQ1700E
1.0
3.5
7.0
1.0
3.5
7.0
1.0
3.5
7.0
LMX2531LQ1910E
1.0
3.5
7.0
LMX2531LQ2080E
1.0
3.5
7.0
LMX2531LQ2265E
1.0
3.5
7.0
LMX2531LQ2570E
0.0
3.0
6.0
LMX2531LQ1570E
1.0
3.0
6.0
LMX2531LQ1650E
1.0
3.0
6.0
LMX2531LQ1700E
1.0
3.0
6.0
LMX2531LQ1742
1.0
3.0
6.0
LMX2531LQ1742
LMX2531LQ1778E
pFout
Output Power to a 50Ω/5pF Load
(Applies across entire tuning range.)
LMX2531LQ1778E
Divider Disabled
1.0
3.0
6.0
LMX2531LQ1910E
1.0
3.0
6.0
LMX2531LQ2080E
0.0
2.5
5.0
LMX2531LQ2265E
0.0
2.5
5.0
LMX2531LQ2570E
-1.0
1.5
4.0
Divider Enabled
LMX2531LQ1570E
KVtune
Fine Tuning Sensitivity
(When a range is displayed in the
typical column, indicates the lower
sensitivity is typical at the lower end
of the tuning range, and the higher
tuning sensitivity is typical at the
higher end of the tuning range.)
°C
4-7
LMX2531LQ1700E
6-10
LMX2531LQ1742
4-7
LMX2531LQ1778E
6-10
LMX2531LQ1910E
8-14
LMX2531LQ2080E
9-20
LMX2531LQ2265E
10-16
LMX2531LQ2570E
10-23
MHz/V
Divider Disabled
-30
-25
Divider Enabled
-20
-15
Divider Disabled
-40
-35
Divider Enabled
LMX2531LQ1570E
LMX2531LQ1650E
-20
-15
Divider Enabled
All Other Options
-25
-20
Frequency Pushing
Creg = 0.1uF, VDD ± 100mV, Open Loop
300
PULLFout
Frequency Pulling
VSWR=2:1, Open Loop
ZFout
Output Impedance
HSFout
PUSHFout
Harmonic Suppression
(Applies Across Entire Tuning
Range)
3rd Harmonic, 50Ω /
5pF Load
dBc
kHz/V
±600
50
7
dBm
4-7
LMX2531LQ1650E
2nd Harmonic, 50Ω /
5pF Load
dBm
kHz
Ω
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LMX2531
Symbol
LMX2531
Symbol
Parameter
Conditions
Min
Typ
Max
Units
VCO Phase Noise (Note 4)
fFout = 1583 MHz
DIV2 = 0
L(f)Fout
Phase Noise
(LMX2531LQ1570E)
fFout = 791.5 MHz
DIV2 = 1
fFout = 1645 MHz
DIV2 = 0
L(f)Fout
Phase Noise
(LMX2531LQ1650E)
fFout = 822.5 MHz
DIV2 = 1
fFout = 1716 MHz
DIV2 = 0
L(f)Fout
Phase Noise
(LMX2531LQ1700E)
fFout = 858 MHz
DIV2 = 1
fFout= 1813 MHz
L(f)Fout
Phase Noise
(LMX2531LQ1742)
fFout = 906.5 MHz
DIV2 = 1
fFout = 1783 MHz
L(f)Fout
Phase Noise
(LMX2531LQ1778E)
fFout = 891.5 MHz
fFout = 1931
L(f)Fout
Phase Noise
(LMX2531LQ1910E)
fFout = 965.5
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8
10 kHz Offset
-93
100 kHz Offset
-118
1 MHz Offset
-140
5 MHz Offset
-154
10 kHz Offset
-99
100 kHz Offset
-122
1 MHz Offset
-144
5 MHz Offset
-155
10 kHz Offset
-93
100 kHz Offset
-118
1 MHz Offset
-140
5 MHz Offset
-154
10 kHz Offset
-99
100 kHz Offset
-122
1 MHz Offset
-144
5 MHz Offset
-155
10 kHz Offset
-92
100 kHz Offset
-117
1 MHz Offset
-139
5 MHz Offset
-153
10 kHz Offset
-98
100 kHz Offset
-122
1 MHz Offset
-144
5 MHz Offset
-154
10 kHz Offset
-92
100 kHz Offset
-117
1 MHz Offset
-140
5 MHz Offset
-152
10 kHz Offset
-99
100 kHz Offset
-122
1 MHz Offset
-143
5 MHz Offset
-152
10 kHz Offset
-92
100 kHz Offset
-117
1 MHz Offset
-139
5 MHz Offset
-152
10 kHz Offset
-97
100 kHz Offset
-122
1 MHz Offset
-144
5 MHz Offset
-154
10 kHz Offset
-89
100 kHz Offset
-115
1 MHz Offset
-138
5 MHz Offset
-151
10 kHz Offset
-95
100 kHz Offset
-121
1 MHz Offset
-143
5 MHz Offset
-155
dBc/Hz
dBc/Hz
dBc/Hz
dBc/Hz
dBc/Hz
dBc/Hz
Parameter
Conditions
fFout = 2089 MHz
L(f)Fout
Phase Noise
(LMX2531LQ2080E)
fFout = 1044.5 MHz
fFout = 2264 MHz
L(f)Fout
Phase Noise
(LMX2531LQ2265E)
fFout = 1132 MHz
fFout = 2563 MHz
L(f)Fout
Phase Noise
(LMX2531LQ2570E)
fFout = 1281.5 MHz
9
Min
Typ
10 kHz Offset
-87
100 kHz Offset
-113
1 MHz Offset
-136
5 MHz Offset
-150
10 kHz Offset
-93
100 kHz Offset
-119
1 MHz Offset
-142
5 MHz Offset
-154
10 kHz Offset
-88
100 kHz Offset
-113
1 MHz Offset
-136
5 MHz Offset
-150
10 kHz Offset
-94
100 kHz Offset
-118
1 MHz Offset
-141
5 MHz Offset
-154
10 kHz Offset
-86
100 kHz Offset
-112
1 MHz Offset
-135
5 MHz Offset
-149
10 kHz Offset
-91
100 kHz Offset
-117
1 MHz Offset
-139
5 MHz Offset
-152
Max
Units
dBc/Hz
dBc/Hz
dBc/Hz
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LMX2531
Symbol
LMX2531
Symbol
Parameter
Conditions
VIH
High-Level Input Voltage
Min
Typ
Max
Units
2.75
V
Digital Interface (DATA, CLK, LE, CE, Ftest/LD, FLout)
1.6
VIL
Low-Level Input Voltage
IIH
High-Level Input Current
VIH = 1.75
-3.0
IIL
Low-Level Input Current
VIL = 0 V
-3.0
VOH
High-Level Output Voltage
IOH = 500 µA
2.0
Low-Level Output Voltage
IOL = -500 µA
VOL
0.4
V
3.0
µA
3.0
µA
2.65
0.0
V
0.4
V
MICROWIRE Timing
tCS
Data to Clock Set Up Time
See Data Input Timing
25
ns
tCH
Data to Clock Hold Time
See Data Input Timing
20
ns
tCWH
Clock Pulse Width High
See Data Input Timing
25
ns
tCWL
Clock Pulse Width Low
See Data Input Timing
25
ns
tES
Clock to Enable Set Up Time
See Data Input Timing
25
ns
tCES
Enable to Clock Set Up Time
See Data Input Timing
25
ns
tEWH
Enable Pulse Width High
See Data Input Timing
25
ns
Note 2: Normalized Phase Noise Contribution is defined as: LN(f) = L(f) – 20log(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 and Fcomp is the comparison frequency of the synthesizer. The offset frequency, f, must be chosen
sufficiently smaller then the loop bandwidth of the PLL, and large enough to avoid a substantial noise contribution from the reference.
Note 3: Maximum Allowable Temperature Drift for Continuous Lock is how far the temperature can drift in either direction from the value it was at the time that
the R0 register was last programmed, and still have the part stay in lock. The action of programming the R0 register, even to the same value, activates a frequency
calibration routine. This implies that the part will work over the entire frequency range, but if the temperature drifts more than the maximum allowable drift for
continuous lock, then it will be necessary to reload the R0 register to ensure that it stays in lock. Regardless of what temperature the part was initially programmed
at, the temperature can never drift outside the frequency range of -40°C ≤TA≤ 85°C without violating specifications.
Note 4: The VCO phase noise is measured assuming that the loop bandwidth is sufficiently narrow that the VCO noise dominates. The maximum limits apply
only at center frequency and over temperature, assuming that the part is reloaded at each test frequency. Over frequency, the phase noise can vary 1-2 dB, with
the worst case performance typically occurring at the highest frequency. Over temperature, the phase noise typically varies 1-2 dB, assuming the part is reloaded.
Serial Data Timing Diagram
20101103
Note that the DATA is clocked into a shift register on each rising edge of the CLK signal. On the rising edge of the LE signal, the
data is sent from the shift registers to an acutal counter. After the programming is complete, the CLK, DATA, and LE signals should
be returned to a low state. Although not recommended, LE can be kept high if bit R5[23] is changed to 0 (from its default value of
1). If this bit is changed, then the operation of the part is not guaranteed because it is not tested under these conditions. National
Semiconductor strongly recommends keeping LE low after programming.
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10
The LMX2531 is a low power, high performance frequency
synthesizer system which includes the PLL, VCO, and partially integrated loop filter. Section 2.0 on programming describes the bits mentioned in this section in more detail.
1.1 REFERENCE OSCILLATOR INPUT
Because the VCO frequency calibration algorithm is based on
clocks from the OSCin pin, there are certain bits that need to
be
set
depending
on
the
OSCin
frequency.
XTLSEL ( R6[22:20] ) and XTLDIV ( R7[9:8] ) are both need
to be set based on the OSCin frequency. For the
LMX2531LQ2080E and the LMX2531LQ2570E, the
XTLMAN ( R7[21:10] ) and XTLMAN2 ( R8[4] ) words need to
be set to the correct value, for all other options, this is not
necessary.
1.2 R DIVIDER
The R divider divides the OSCin frequency down to the phase
detector frequency. The only valid R counter values are 1, 2,
4, 8, 16, and 32. The R divider also has an impact on the
fractional modulus that can be used, if it is greater than 8.
1.4 PHASE DETECTOR
The phase detector compares the outputs of the R and N
counters and puts out a correction current corresponding to
the phase error. The choice of the phase detector frequency
does have an impact on performance. When determining
which phase detector frequency to use, the restrictions on the
R counter values must be taken into consideration.
1.3 N DIVIDER AND FRACTIONAL CIRCUITRY
The N divider on the LMX2531 is fractional and can achieve
any fractional denominator between 1 and 4,194,303. The integer portion of the N counter value, NInteger, is determined by
the value of the N word. Because there is a 16/17/20/21
prescaler, there are restrictions on how small the NInteger value
can be. This is because this value is actually formed by several different prescalers in the quadruple modulus prescaler
in order to achieve the desired value. The fractional word,
NFractional , is a fraction formed with the NUM and DEN words.
The fractional denominator value, DEN, can be set from 2 to
4,194,303. The case of DEN=0 makes no sense, since this
would cause an infinite N value, and the case of 1 makes no
sense (but could be done), because integer mode should be
used in these applications. All other values in this range, like
10, 32,734, or 4,000,000 are all valid. Once the fractional denominator, DEN, is determined, the fractional numerator,
NUM, is intended to be varied from 0 to DEN-1. Sometimes,
expressing the same fraction, like 1/10, in terms of larger
fractions, like 100/10000, sometimes yields better fractional
spurs, but other times it does not. This can be impacted by
the fractional modulator order and the dithering mode selected, as well as the loop bandwidth, and other application
specific criteria. So in general, the total N counter value is
determined by:
1.5 PARTIALLY INTEGRATED LOOP FILTER
The LMX2531 integrates the third pole (formed by R3 and C3)
and fourth pole (formed by R4 and C4) of the loop filter. This
loop filter can be enabled or bypassed using the
EN_LPFLTR ( R6[15] ). The values for C3, C4, R3, and R4
can also be programmed independently through the MICROWIRE interface . Also, the values for R3 and R4 can be
changed during FastLock, for minimum lock time. It is recommended that the integrated loop filter be set to the maximum
possible attenuation (R3=R4=40kΩ, C3=C4=100pF), the internal loop filter is more effective at reducing certain spurs
than the external loop filter. However, if the attenuation of the
internal loop filter is too high, it limits the maximum attainable
loop bandwidth that can be achieved, which corresponds to
the case where the shunt loop filter capacitor, C1, is zero.
Increasing the charge pump current and/or the comparison
frequency increases the maximum attainable loop bandwidth
when designing with the integrated filter. Furthermore, this
often allows the loop filter to be better optimized and have
stronger attenuation. If the charge pump current and comparison frequency are already as high as they go, and the
maximum attainable loop bandwidth is still too low, the resistor and capacitor values can be decreased or the internal loop
filter can even be bypassed. Note that when the internal loop
filter is bypassed, there is still a small amount of input capacitance on front of the VCO on the order of 200 pF. For design
tools and more information on partially integrated loop filters,
go to wireless.national.com.
N = NInteger + NFractional
In order to calculate the minimum necessary fractional denominator, the R counter value needs to be chosen, so that
the comparison frequency is known. The minimum necessary
fractional denominator can be calculated by dividing the comparison frequency by the greatest common multiple of the
comparison frequency and the OSCin frequency. For example, consider the case of a 10 MHz crystal and a 200 kHz
channel spacing. If the R counter value is chosen to be 2, then
the comparison frequency will be 5 MHz. The greatest common multiple of 200 kHz and 5 MHz is 200 kHz. If one takes
5 MHz divided by 200 kHz, this is 25. So a fractional denominator of 25, or any multiple of 25 would work in this situation.
Now consider a second example where the channel spacing
is changed to 30 kHz. If it is again assumed that the comparison frequency is 5 MHz, then the greatest common multiple
of 30 kHz and 5 MHz is 10 kHz. 5 MHz divided by 10 kHz is
500. In this situation, a fractional denominator of 500, or any
1.6 LOW NOISE, FULLY INTEGRATED VCO
The LMX2531 includes a fully integrated VCO, including the
inductors. In order for optimum phase noise performance, this
VCO has frequency and phase noise calibration algorithms.
The frequency calibration algorithm is necessary because the
VCO internally divides up the frequency range into several
bands, in order to achieve a lower tuning gain, and therefore
better phase noise performance. The frequency calibration
routine is activated any time that the R0 register is programmed. If the temperature shifts considerably and the R0
11
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LMX2531
multiple of 500 would suffice. For a final example, consider
an application with a fixed output frequency of 2110.8 MHz
and a crystal frequency of 19.68 MHz. If the R counter is chosen to be 2, then the comparison frequency is 9.84 MHz. The
greatest common multiple of 9.84 MHz and 2110.8 MHz is
240 kHz. 9.84 MHz / 240 kHz = 41. So the fractional denominator could be 41, or any multiple of 41. For this last example
value, the entire N counter value would be 214 + 21/41.
The fractional value is achieved with a delta sigma architecture. In this architecture, an integer N counter is modulated
between different values in order to achieve a fractional value.
On this part, the modulator order can be zero (integer mode),
two, three, or four. The higher the fractional modulator order
is, the lower the spurs theoretically are. However, this is not
always the case, and the higher order fractional modulator
can sometimes give rise to additional spurious tones, but this
is dependent on the application. This is why it is an advantage
to have the modulator order selectable. Dithering also has an
impact on the fractional spurs, but a lesser one.
1.0 Functional Description
LMX2531
register is not programmed, then it can not drift more than the
maximum allowable drift for continuous lock, ΔTCL, or else the
VCO is not guaranteed to stay in lock. The phase noise calibration algorithm is necessary in order to achieve the lowest
possible phase noise. Each version of the LMX2531, the
VCO_ACI_SEL bit ( R6[19:16] ) needs to be set to the correct
value to ensure the best possible phase noise.
The gain of the VCO can change considerably over frequency. It is lowest at the minimum frequency and highest at the
maximum frequency. This range is specified in the datasheet.
When designing the loop filter, the following method is recommended. First, take the geometric mean of the minimum
and maximum frequencies that are to be used. Then use a
linear approximation to extrapolate the VCO gain. An example is in order. Suppose the application requires the
LMX2531LQ2080E PLL to tune from 2100 to 2150 MHz. The
geometric mean of these frequencies is sqrt(2100 × 2150)
MHz = 2125 MHz. The VCO gain is specified as 9 MHz/V at
1904 MHz and 20 MHz/V at 2274 MHz. Over this range of 370
MHz, the VCO gain changes 11 MHz/V. So at 2125 MHz, the
VCO gain would be approximately 9 + (2125-1904)* 11/370
= 15.6 MHz/V. Although the VCO gain can change from part
to part, this variation is small to how much the VCO gain can
change over frequency.
VCO frequency before it is divide by two. Note that R0 register
should be reprogrammed the first time after the DIV2 bit is
enabled or disabled for optimal phase noise performance.
1.8 CHOOSING THE CHARGE PUMP CURRENT AND
COMPARISON FREQUENCY
The LMX2531 has 16 levels of charge pump currents and a
highly flexible fractional modulus. This gives the user many
degrees of freedom. This section discusses some of the design considerations. From the perspective of the PLL noise,
choosing the charge pump current and comparison frequency
as high as possible are best for optimal phase noise performance. The far out PLL noise improves 3 dB for every doubling of the comparison frequency, but at lower offsets, this
effect is much less due to the PLL 1/f noise. Increasing the
charge pump current improves the phase noise about 3 dB
per doubling of the charge pump current, although there are
small diminishing returns as the charge pump current goes
higher.
From a loop filter design and PLL phase noise perspective,
one might think to always design with the highest possible
comparison frequency and charge pump current. However, if
one considers the worst case fractional spurs that occur at an
output frequency equal to 1 channel spacing away from a
multiple of the OSCin frequency, then this gives reason to reconsider. If the comparison frequency or charge pump currents are too high, then these spurs could be degraded, and
the loop filter may not be able to filter these spurs as well as
theoretically predicted. For optimal spur performance, a comparison frequency in the ballpark of 2.5 MHz and a charge
pump current of 1X are recommended.
1.7 PROGRAMMABLE DIVIDE BY 2
All options of the LMX2531 offer a divide by 2 option. This
allows the user to get exactly half of the VCO frequency, by
dividing the output of the VCO output by two. Because this
divide by two is outside feedback path between the VCO and
the PLL, the loop filter and counter values are set up for the
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12
The LMX2531 is programmed using 11 24-bit registers used to control the LMX2531 operation. A 24-bit shift register is used as a
temporary register to indirectly program the on-chip registers. The shift register consists of a data field and an address field. The
last 4 register bits, CTRL[3:0] form the address field, which is used to decode the internal register address. The remaining 20 bits
form the data field DATA[19:0]. While LE is low, serial data is clocked into the shift register upon the rising edge of clock (data is
programmed MSB first). When LE goes high, data is transferred from the data field into the selected register bank. Although there
are actually 14 registers in this part, only a portion of them should be programmed, since the state of the other hidden registers
(R13, R11, and R10) are set during the initialization sequence. Although it is possible to program these hidden registers, as well
as a lot of bits that are defined to either '1' or '0', the user should not experiment with these hidden registers and bits, since the
parts are not tested under these conditions and doing so will most likely degrade performance.
DATA[19:0]
CONTROL[3:0]
MSB
D19
LSB
D18
D17
D16
D15
D14
D13
D12
D11
D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 C3 C2 C1
C0
2.01 Register Location Truth Table
C3
C2
C1
C0
Data Address
1
1
0
0
R12
1
0
0
1
R9
1
0
0
0
R8
0
1
1
1
R7
0
1
1
0
R6
0
1
0
1
R5
0
1
0
0
R4
0
0
1
1
R3
0
0
1
0
R2
0
0
0
1
R1
0
0
0
0
R0
2.02 Initialization Sequence
The initial loading sequence from a cold start is described below. The registers must be programmed in order shown. There must
be a minimum of 10 ms between the time when R5 is last loaded and R1 is loaded to ensure time for the LDOs to power up properly.
REG.
23
22
21
20
19
18
17
16
15
14
13
12
11
10
9
8
7
6
5
4
DATA[19:0]
3
2
1
0
C3 C2 C1 C0
R5
INIT1
1
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
R5
INIT2
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
1
R5
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
0
1
0
1
Program R12 as shown in the complete register map.
1
1
0
0
R9
Program R9 as shown in the complete register map.
1
0
0
1
R8
See individual section for Register R8 programming information.
Program Register R8 only for the 2080E and 2570E versions when fOSCin > 40 MHz.
1
0
0
0
R7
See individual section for Register R7 programming information.
0
1
1
1
R6
See individual section for Register R6 programming information.
0
1
1
0
R4
See individual section for Register R4 programming information.
Register R4 only needs to be programmed if FastLock is used.
0
1
0
0
R3
See individual section for Register R3 programming information.
0
0
1
1
R2
See individual section for Register R2 programming information.
0
0
1
0
R1
See individual section for Register R1 programming information.
0
0
0
1
R0
See individual section for Register R0 programming information.
0
0
0
0
R12
13
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LMX2531
2.0 General Programming Information
FD
M
DIV
2
0
1
R3
R4
R5
14
0
0
0
0
0
R7
R8
R9
R12
0
0
0
R6
0
0
0
1
R2
0
0
0
XTLSEL
[2:0]
0
0
0
0
0
ICP
[3:0]
18
ORDER
[1:0]
0
0
0
0
ICPFL
[3:0]
DITHER
[1:0]
0
0
0
R1
19
N
[7:0]
20
0
17
0
0
0
0
0
1
N
[10:8]
15
0
1
0
1
0
0
0
XTLMAN
[11:0]
0
FoLD
[3:0]
DEN
[11:0]
16
VCO_ACI_SEL
[3:0]
REG_RST
R0
21
1
22
EN_LPFLTR
23
13
0
0
0
0
0
0
0
R4_ADJ
[1:0]
0
DATA[19:0]
14
0
0
0
0
0
1
0
9
1
0
EN_PLLLDO1
0
1
0
0
1
0
XTLDIV
[1:0]
1
1
0
0
R3_ADJ_
FL
[1:0]
DEN
[21:12]
R3_ADJ
[1:0]
0
8
EN_OSC
0
0
0
0
0
1
0
0
0
0
0
0
1
0
0
0
0
0
0
1
1
1
XTL
MA
N2
0
0
0
1
0
0
1
1
1
C2
C3
0
2
3
0
C3_4_ADJ
[2:0]
4
5
EN_VCO
6
R
[5:0]
7
EN_VCOLD
NUM
[21:12]
NUM
[11:0]
10
TOC
[13:0]
11
R4_ADJ_
FL
[1:0]
0
12
EN_DIGLDO
RE
GIS
TER
EN_PLL
LMX2531
0
0
0
1
1
0
0
1
1
0
0
C1
1
0
1
0
1
0
1
0
1
0
1
0
C0
0
This table shows all the programmable bits for the LMX2531. No programming order or initialization sequence is implied by this table, only the location of the programming information.
2.03 Complete Register Content Map
EN_PLLLDO2
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The action of programming the R0 register activates a frequency calibration routine for the VCO. This calibration is necessary to
get the VCO to center the tuning voltage for optimal performance. If the temperature drifts considerably, then the PLL should stay
in lock, provided that the temperature drift specification is not violated.
2.1.1 NUM[10:0] and NUM[21:12] -- Fractional Numerator
The NUM word is split between the R0 register and R1 register. The Numerator bits determine the fractional numerator for the
delta sigma PLL. This value can go from 0 to 4095 when the FDM bit ( R3[22] ) is 0 (the other bits in this register are ignored), or
0 to 4194303 when the FDM bit is 1.
NUM[21:12]
NUM[11:0]
Fractional
Numerator
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
409503
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
4096
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
...
...
4194303
Note that there are restrictions on the fractional numerator value depending on the R counter value if it is 16 or 32.
2.1.2 N[7:0] and N[10:8]
The N counter is 11 bits. 8 of these bits are located in the R0 register, and the remaining 3 (MSB bits) are located in the R1 register.
The LMX2531 consists of an A, B, and C counter, which work in conjunction with the 16/17/20/21 prescaler in order to form the
final N counter value.
N[10:8]
N[7:0]
N Value
C
<55
55
B
A
Values less than 55 are prohibited.
0
0
0
0
0
1
1
0
1
1
1
1
1
1
1
1
1
1
0
1
1
1
...
2039
15
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LMX2531
2.1 REGISTER R0
LMX2531
2.2 REGISTER R1
2.2.1 NUM[21:12]
These are the MSB bits in for the fractional numerator that already have been described.
2.2.2 N[10:8] -- 3 MSB Bits for the N Counter
These are the 2 MSB bits for the N counter, which were discussed in the R0 register section.
2.2.3 ICP[3:0] -- Charge Pump Current
This bit programs the charge pump current when the charge pump gain. The current is programmable between 100uA and 1.6mA
in 100uA steps. In general, higher charge pump currents yield better phase noise for the PLL, but also can cause higher spurs.
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Typical Charge Pump Current at 3 Volts
(µA)
ICP
Charge Pump State
0
1X
90
1
2X
180
2
3X
270
3
4X
360
4
5X
450
5
6X
540
6
7X
630
7
8X
720
8
9X
810
9
10X
900
10
11X
990
11
12X
1080
12
13X
1170
13
14X
1260
14
15X
1350
15
16X
1440
16
LMX2531
2.3 REGISTER R2
2.3.1 R[5:0] -- R Counter Value
These bits determine the phase detector frequency. The OSCin frequency is divided by this R counter value. Note that only the
values of 1, 2, 4, 8, 16, and 32 are allowed.
R Value
Fractional
Denominator
Restrictions
R[5:0]
0,3,5-7,
9-15,17-31,
33-63
n/a
These values are illegal.
1
none
0
0
0
0
0
1
2
none
0
0
0
0
1
0
4
none
0
0
0
1
0
0
8
none
0
0
1
0
0
0
16
Must be
divisible by 2
0
1
0
0
0
0
32
Must be
divisible by 4
1
0
0
0
0
0
Note that the R counter value can put some restrictions on the fractional denominator. In the case that it is 16, the fractional
denominator must be divisible by 2, which is equivalent to saying that the LSB of the fractional denominator word is zero. In the
case that the R counter is 32, the two LSB bits of the fractional denominator word must also be zero, which is equivalent to saying
that the fractional denominator must be divisible by 4. Because the fractional denominator can be very large, this should cause no
issues. For instance, if one wanted to achieve a fractional word of 1/65, and the R counter value was 16, the fractional word could
be changed t0 4/260 ,and the same resolution could be achieved.
2.3.2 DEN[21:12] and DEN[11:0]-- Fractional Denominator
These bits determine the fractional denominator. Note that the MSB bits for this word are in register R3. If the FDM bit is set to 0,
DEN[21:12] are ignored. The fractional denominator should only be set to zero if the fractional circuitry is being disabled by setting
ORDER=1. A value of one never makes sense to use. All other values could reasonably be used in fractional mode.
DEN[21:12]
DEN[11:0]
Fractional
Denominator
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4095
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
4096
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
...
...
4194303
17
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LMX2531
2.4 REGISTER R3
2.4.1 DEN[21:12] -- Extension for the Fractional Denominator
These are the MSB bits of the DEN word, which have already been discussed.
2.4.2 FoLD[3:0] -- Multiplexed Output for Ftest/LD Pin
The FoLD[3:0] word is used to program the output of the Ftest/LD Pin. This pin can be used for a general purpose I/O pin, a lock
detect pin, and for diagnostic purposes. When programmed to the digital lock detect state, the output of the Ftest/LD pin will be
high when the part is in lock, and low otherwise. Lock is determined by comparing the input phases to the phase detector. The
analog lock detect modes put out a high signal with very fast negative pulses, that correspond to when the charge pump comes
on. This output can be low pass filtered with an RC filter in order to determine the lock detect state. If the open drain state is used,
a pull-up resistor that is much larger than the resistance in the RC filter, to increase the sensitivity of the circuit. For diagnostic
purposes, the options that allow one to view the output of the R counter or the N counter can be very useful. Be aware that the
output voltage level of the Ftest/LD is not equal to the supply voltage of the part, but rather is given by VOH and VOL in the electrical
characteristics specification.
FoLD
Output Type
Function
0
High Impedance
Disabled
1
Push-Pull
Logical High State
2
Push-Pull
Logical Low State
3
Push-Pull
Digital Lock Detect
4
N/A
Reserved
5
Push-Pull
N Counter Output Divided by 2
6
Open-Drain
Analog Lock Detect
7
Push-Pull
Analog Lock Detect
8
N/A
Reserved
9
N/A
Reserved
10
N/A
Reserved
11
N/A
Reserved
12
N/A
Reserved
13
N/A
Reserved
14
Push-Pull
R Counter Output
15
N/A
Reserved
2.4.3 ORDER -- Order of Delta Sigma Modulator
This bit determines the order of the delta sigma modulator in the PLL. In general, higher order fractional modulators tend to reduce
the primary fractional spurs that occur at increments of the channel spacing, but can also create spurs that are at a fraction of the
channel spacing, if there is not sufficient filtering. The optimal choice of modulator order is very application specific, however, a
third order modulator is a good starting point if not sure what to try first.
ORDER
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Delta Sigma Modulator Order
0
Fourth
1
Reset Modulator
(Integer Mode - all fractions are ignored)
2
Second
3
Third
18
Dithering is useful in reducing fractional spurs, especially those that occur a a fraction of the channel spacing. The only exception
is when the fractional numerator is zero. In this case, dithering usually is not a benefit. Dithering also can sometimes increase the
PLL phase noise by a fraction of a dB. In general, if dithering is disabled, phase noise may be slightly better inside the loop bandwidth
of the system, but spurs are likely to be worse too.
DITHER
Dithering Mode
0
Weak Dithering
1
Reserved
2
Strong Dithering
3
Dithering Disabled
2.4.5 FDM -- Fractional Denominator Mode
When this bit is set to 1, the 10 MSB bits for the fractional numerator and denominator are considered. This allows the fractional
denominator to range from 1 to 4,194,303. If this bit is set to zero, only the 12 LSB bits of the fractional numerator and denominator
are considered, and this allows a fractional denominator from 1 to 4095. When this bit is disabled, the current consumption is about
0.5 mA lower.
2.4.6 -- DIV2
When this bit is enabled on the appropriate option, the output of the VCO is divided by 2 on options that offer this feature. This has
a small impact on harmonic content and output power.
DIV2
VCO Output Frequency
0
Not Divided by 2
1
Divided by 2
19
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LMX2531
2.4.4 DITHER -- Dithering
LMX2531
2.5 REGISTER R4
2.5.1 TOC[13:0] -- Time Out Counter for FastLock
When the value of this word is 3 or less, then FastLock is disabled, and this pin can only be used for general purpose I/O. When
this value is 4 or greater, the time out counter is engaged for the amount of phase detector cycles shown in the table below.
TOC Value
FLout Pin State
Timeout Count
0
High Impedance
0
1
Low
Always Enabled
2
Low
0
3
High
0
4
Low
4 X 2 Phase Detector
.
.
.
16383
Low
16383 X 2 Phase Detector
When this count is active, the FLout Pin is grounded, the FastLock current is engaged, and the resistors R3 and R4 are also
potentially changed. The table below summarizes the bits that control various values in and out of FastLock differences.
FastLock State
FLout
Charge Pump Current
R3
R4
Steady State
High Impedance
ICP
R3_ADJ
R4_ADJ
Fastlock
Grounded
ICPFL
R3_ADJ_FL
R4_ADJ_FL
2.5.2 ICPFL[3:0] -- Charge Pump Current for Fastlock
When FastLock is enabled, this is the charge pump current that is used for faster lock time.
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Typical Fastlock Charge Pump Current
at 3 Volts (µA)
ICPFL
Fastlock Charge Pump State
0
1X
90
1
2X
180
2
3X
270
3
4X
360
4
5X
450
5
6X
540
6
7X
630
7
8X
720
8
9X
810
9
10X
900
10
11X
990
11
12X
1080
12
13X
1170
13
14X
1260
14
15X
1350
15
16X
1440
20
LMX2531
2.6 REGISTER R5
2.6.1 EN_PLL -- Enable Bit for PLL
When this bit is set to 1, the PLL is powered up, otherwise, it is powered down.
2.6.2 EN_VCO -- Enable Bit for the VCO
When this bit is set to 1, the VCO is powered up, otherwise, it is powered down.
2.6.3 EN_OSC -- Enable Bit for the Oscillator Inverter
When this bit is set to 1 (default), the reference oscillator is powered up, otherwise it is powered down.
2.6.4 EN_VCOLDO -- ENABLE BIT FOR THE VCO LDO
When this bit is set to 1 (default), the VCO LDO is powered up, otherwise it is powered down.
2.6.5 EN_PLLLDO1 -- ENABLE BIT FOR THE PLL LDO 1
When this bit is set to 1 (default), the PLL LDO 1 is powered up, otherwise it is powered down.
2.6.6 EN_PLLLDO2 -- ENABLE BIT FOR THE PLL LDO 2
When this bit is set to 1 (default), the PLL LDO 2 is powered up, otherwise it is powered down.
2.6.7 EN_DIGLDO -- ENABLE BIT FOR THE DIGITAL LDO
When this bit is set to 1 (default), the Digital LDO is powered up, otherwise it is powered down.
2.6.8 REG_RST -- RESETS ALL REGISTERS TO DEFAULT SETTINGS
This bit needs to be programmed three times to initialize the part. When this bit is set to one, all registers are set to default mode,
and the part is powered down. The second time the R5 register is programmed with REG_RST=0, the register reset is released
and the default states are still in the registers. However, since the default states for the blocks and LDOs is powered off, it is
therefore necessary to program R5 a third time so that all the LDOs and blocks can be programmed to a power up state. When
this bit is set to 1, all registers are set to the default modes, but part is powered down. For normal operation, this bit is set to 0.
Note that once this initialization is done, it is not necessary to initialize the part any more.
21
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LMX2531
2.7 REGISTER R6
2.7.1 C3_C4_ADJ[2:0] -- VALUE FOR C3 AND C4 IN THE INTERNAL LOOP FILTER
C3_C4_ADJ
C3 (pF)
0
50
C4 (pF)
50
1
50
100
2
50
150
3
100
50
4
150
50
5
100
100
6
50
150
7
50
150
2.7.2 R3_ADJ_FL[1:0] -- Value for Internal Loop Filter Resistor R3 During Fastlock
R3_ADJ_FL Value
R3 Resistor During Fastlock (kΩ)
0
10
1
20
2
30
3
40
2.7.3 R3_ADJ[1:0] -- Value for Internal Loop Filter Resistor R3
R3_ADJ
R3 Value (kΩ)
0
10
1
20
2
30
3
40
2.7.4 R4_ADJ_FL[1:0] -- Value for Internal Loop Filter Resistor R4 During Fastlock
R4_ADJ_FL
R4 Value during Fast Lock (kΩ)
0
10
1
20
2
30
3
40
2.7.5 R4_ADJ[1:0] -- Value for Internal Loop Filter Resistor R4
R4_ADJ
R4 Value (kΩ)
0
10
1
20
2
30
3
40
2.7.6 EN_LPFLTR-- Enable for Partially Integrated Internal Loop Filter
The Enable Loop Filter bit is used to enable/disable the 3rd and 4th pole on-chip loop filters.
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EN_LPFLTR
3rd and 4th Poles of Loop Filter
0
disabled
(R3 = R4 = 0 ohms and C3 + C4 = 200pF)
1
enabled
22
This bit is used to optimize the VCO phase noise. The recommended values are what are used for all testing purposes, and this
bit should be set as the table below instructs.
Part
VCO_ACI_SEL
LMX2531LQ1570E
LMX2531LQ1650E
LMX2531LQ1700E
LMX2531LQ1742
LMX2531LQ1778E
LMX2531LQ1910E
LMX2531LQ2080E
8
LMX2531LQ2265E
LMX2531LQ2570E
6
2.7.8 XTLSEL[2:0] -- Crystal Select
XTLSEL
Crystal Frequency
0
<25 MHz
1
25 - 50 MHz
2
50 - 70 MHz
3
>70 MHz
4
Manual Mode
5
Reserved
6
Reserved
7
Reserved
The value of this word needs to be changed based on the frequency presented to the OSCin pin in accordance to the table above.
Manual mode must be used for the LMX2531LQ2080E and the LMX2531LQ2570 only. The other options should use modes 0 3.
2.8 REGISTER R7
2.8.1 XTLDIV[1:0] -- Division Ratio for the Crystal Frequency
The frequency provided to the VCO frequency calibration circuitry is based on the OSCin frequency divided down by a factor,
determined by the XTLDIV word. Note that this division ratio is independent of the R counter value or the comparison frequency.
The necessary division ratio depends on the OSCin frequency and is shown in the table below:
XTLDIV
Crystal Division Ratio
0
Reserved
Crystal Range
Reserved
1
Divide by 2
< 20 MHz
2
Divide by 4
20-40 MHz
3
Divide by 8
> 40 MHz
2.8.2 XTLMAN[11:0] -- Manual Crystal Mode
This word adjusts the calibration timing for lock time. With the exception of the parts listed in the table below, this bit should be set
to zero for normal operation. For those parts in the table. For fOSCin frequencies (expressed in MHz) not shown in the table, this bit
value can be calculated as 16 X fOSCin / Kbit.
Part
Kbit
LMX2531LQ208
0E
LMX2531LQ257
0E
fOSCin
10 MHz
20 MHz
30.72 MHz
61.44 MHz
76.8 MHz
4.5
36
71
109
218
273
6.0
27
53
82
164
205
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LMX2531
2.7.7 VCO_ACI_SEL
LMX2531
2.9 REGISTER R8
2.9.1 XTLMAN2 -- MANUAL CRYSTAL MODE SECOND ADJUSTMENT
This bit also adjusts the calibration timing for lock time. In the case that manual mode for XTLSEL is selected and the OSCin
frequency is greater than 40 MHz, this bit should be enabled, otherwise it should be 0.
2.10 REGISTER R9
All the bits in this register should be programmed as shown in the programming table.
2.11 REGISTER R12
Even though this register does not have user selectable bits, it still needs to be programmed. This register should be loaded as
shown in section 2.02 Complete Register Content Map.
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24
LMX2531
Physical Dimensions inches (millimeters) unless otherwise noted
Leadless Leadframe Package (Bottom View)
Order Number LMX2531LQX for 2500 Unit Reel
Order Number LMX2531LQ for 250 Unit Reel
NS Package Number LQA036AA
Marking
Part
Marking
LMX2531LQ1570E
311570EB
LMX2531LQ1910E
311910EB
LMX2531LQ1650E
311650EA
LMX2531LQ2080E
312080EB
LMX2531LQ1700E
311778EB
LMX2531LQ2265E
312265ED
LMX2531LQ1742
311742EA
LMX2531LQ2570E
312570EC
LMX2531LQ1778E
311778EA
Part
25
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LMX2531 High Performance Frequency Synthesizer System with Integrated VCO
Notes
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