TI1 LMX2492RTWR Low noise fractional n pll Datasheet

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LMX2492, LMX2492-Q1
SNAS624B – MARCH 2014 – REVISED MAY 2015
LMX2492/LMX2492-Q1 14 GHz Low Noise Fractional N PLL with Ramp/Chirp Generation
1 Features
3 Description
•
•
•
•
•
•
•
•
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The LMX2492/92-Q1 is a low noise 14 GHz
wideband delta-sigma fractional N PLL with ramp and
chirp generation. It consists of a phase frequency
detector, programmable charge pump, and high
frequency input for the external VCO. The
LMX2492/92-Q1 supports a broad and flexible class
of ramping capabilities, including FSK, PSK, and
configurable piecewise linear FM modulation profiles
of up to 8 segments. It supports fine PLL resolution
and fast ramp with up to a 200 MHz phase detector
rate. The LMX2492/92-Q1 allows any of its registers
to be read back. The LMX2492/92-Q1 can operate
with a single 3.3 V supply. Moreover, supporting up to
5.25 V charge pump can eliminate the need of
external amplifier, leading to a simpler solution with
improved phase noise performance.
1
2
•
•
•
•
•
•
•
-227 dBc/Hz Normalized PLL Noise
500 MHz - 14 GHz Wideband PLL
3.15 - 5.25 V Charge Pump PLL Supply
Versatile Ramp / Chirp Generation
200 MHz Max Phase Detector Frequency
FSK / PSK Modulation Pin
Digital Lock Detect
Single 3.3 V Supply Capability
Automotive 125°C Q100 Grade 1 Qualification
Non-Automotive (LMX2492) Option
Applications
Automotive FMCW Radar
Military Radar
Microwave Backhaul
Test and Measurement
Satellite Communications
Wireless Infrastructure
Sampling Clock for High Speed ADC/DAC
Device Information
PART NUMBER
PACKAGE
BODY SIZE (NOM)
LMX2492-Q1RTW
WQFN (24)
4.00 mm x 4.00 mm
LMX2492RTW
WQFN (24)
4.00 mm x 4.00 mm
(1) For all available packages, see the orderable addendum at
the end of the datasheet.
4 Simplified Schematic
OSCin
2X
R Divider
(16 bit)
51 :
Phase
Comp
GND/OSCin*
51 :
Charge
Pump
CPout
C2_LF
C1_LF
Vcp
GND (x3)
R2_LF
CLK
DATA
LE
MICROWIRE
Interface
18 :
Fin
Fin*
MOD
36 :
18 :
To Circuit
N Divider
(18 bit)
TRIG1
TRIG2
18 :
Vcc (x5)
CE
MUX
Modulation
Generator
6'
Compensation
(24 bit)
68 :
51 :
MUXout
1
An IMPORTANT NOTICE at the end of this data sheet addresses availability, warranty, changes, use in safety-critical applications,
intellectual property matters and other important disclaimers. PRODUCTION DATA.
LMX2492, LMX2492-Q1
SNAS624B – MARCH 2014 – REVISED MAY 2015
www.ti.com
Table of Contents
1
2
3
4
5
6
7
Features ..................................................................
Applications ...........................................................
Description .............................................................
Simplified Schematic.............................................
Revision History.....................................................
Pin Configuration and Functions .........................
Specifications.........................................................
1
1
1
1
2
3
4
7.1
7.2
7.3
7.4
7.5
7.6
7.7
Absolute Maximum Ratings................................... 4
Storage Conditions.................................................... 4
ESD Ratings ............................................................ 4
Recommended Operating Conditions....................... 4
Thermal Information ................................................. 4
Electrical Characteristics .......................................... 5
Timing Requirements, Programming Interface (CLK,
DATA, LE) .................................................................. 6
7.8 Typical Characteristics ............................................. 7
8
Detailed Description .............................................. 9
8.1
8.2
8.3
8.4
8.5
Overview ................................................................... 9
Functional Block Diagram ......................................... 9
Feature Description................................................... 9
Device Functional Modes........................................ 13
Programming........................................................... 14
8.6
8.7
8.8
8.9
8.10
8.11
9
Register Map...........................................................
Register Field Descriptions .....................................
Lock Detect and Charge Pump Monitoring.............
TRIG1,TRIG2,MOD, and MUXout Pins ..................
Ramping Functions ...............................................
Individual Ramp Controls ......................................
14
18
21
22
24
26
Applications and Implementation ...................... 27
9.1 Application Information............................................ 27
9.2 Typical Applications ................................................ 27
10 Power Supply Recommendations ..................... 33
11 Layout................................................................... 34
11.1 Layout Guidelines ................................................. 34
11.2 Layout Example .................................................... 34
12 Device and Documentation Support ................. 35
12.1
12.2
12.3
12.4
12.5
12.6
12.7
Device Support ....................................................
Documentation Support .......................................
Related Links ........................................................
Community Resources..........................................
Trademarks ...........................................................
Electrostatic Discharge Caution ............................
Glossary ................................................................
35
35
35
35
35
35
35
13 Mechanical, Packaging, and Orderable
Information ........................................................... 36
5 Revision History
Changes from Revision A (June 2014) to Revision B
Page
•
Changed Changed CLK, DATA, and LE to right Input/Output Format .................................................................................. 3
•
Changed terminal to pin ........................................................................................................................................................ 3
•
Changed Same specs, but new format tables for storage and ESD Ratings ....................................................................... 4
•
Changed TYP to NOM ........................................................................................................................................................... 4
•
Added Added comment for lower voltage operation. ............................................................................................................. 5
•
Changed Fixed Diagram. A14 is hightest bit .......................................................................................................................... 6
•
Added note in Applications and Implementation section ..................................................................................................... 27
Changes from Original (March 2014) to Revision A
Page
•
Changed from 35 to 10........................................................................................................................................................... 6
•
Changed from 10 to 4............................................................................................................................................................. 6
•
Changed from 10 to 4............................................................................................................................................................. 6
•
Changed from 25 to 10 .......................................................................................................................................................... 6
•
Changed from 25 t o10........................................................................................................................................................... 6
Ö
2
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SNAS624B – MARCH 2014 – REVISED MAY 2015
6 Pin Configuration and Functions
CPout
Rset
Vcp
TRIG2
TRIG1
Vcc
24 Pin WQFN
RTW Package
(Top View)
24
23
22
21
20
19
GND
1
18 Vcc
GND
2
17 MUXout
GND
3
16 LE
Pin 0
(Ground Substrate)
Fin
4
Fin*
5
14 CLK
Vcc
6
13 CE
8
9
10
11
12
Vcc
OSCin
GND/OSCin*
GND
MOD
Vcc
7
15 DATA
Pin Functions
PIN
NUMBER
NAME
I/O
DESCRIPTION
0
DAP
GND
Die Attach Pad. Connect to PCB ground plane.
1
GND
GND
Ground for charge pump.
2,3
GND
GND
Ground for Fin Buffer
4,5
Fin
Fin*
Input
Complimentary high frequency input pins. Should be AC coupled. If driving single-ended,
impedance as seen from Fin and Fin* pins looking outwards from the part should be roughly the
same.
6
Vcc
Supply
Power Supply for Fin Buffer
7
Vcc
Supply
Supply for On-chip LDOs
8
Vcc
Supply
Supply for OSCin Buffer
9
OSCin
Input
10
GND/
OSCin*
GND/Input
GND
Reference Frequency Input
Complimentary input for OSCin.
If not used, it is recommended to match the termination as seen from the OSCin terminal looking
outwards. However, this may also be grounded as well.
11
GND
12
MOD
Ground for OSCin Buffer
13
CE
Input
Chip Enable
14
CLK
Input
Serial Programming Clock.
15
DATA
Input
Serial Programming Data
16
LE
Input
Serial Programming Latch Enable
17
MUXout
18
Vcc
Supply
Supply for delta sigma engine.
19
Vcc
Supply
Supply for general circuitry.
20
TRIG1
Input/Output Multiplexed Pin for Ramp Triggers, FSK/PSK Modulation, FastLock, Readback, and Diagnostics.
21
TRIG2
Input/Output Multiplexed Pin for Ramp Triggers, FSK/PSK Modulation, FastLock, Readback, and Diagnostics.
22
Vcp
Supply
23
Rset
NC
24
CPout
Output
Input/Output Multiplexed Pin for Ramp Triggers, FSK/PSK Modulation, FastLock, Readback, and Diagnostics.
Input/Output Multiplexed Pin for Ramp Triggers, FSK/PSK Modulation, FastLock, Readback, and Diagnostics.
Power Supply for the charge pump.
No connect.
Charge Pump Output
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7 Specifications
7.1 Absolute Maximum Ratings
over operating free-air temperature range (unless otherwise noted)
(1)
MIN
MAX
UNIT
Vcp
Supply voltage for charge pump
Vcc
5.5
V
CPout
Charge pump output pin
-0.3
Vcp
V
Vcc
All Vcc pins
-0.3
3.6
V
Others
All other I/O pins
-0.3
Vcc + 0.3
V
TSolder
Lead temperature (solder 4 seconds)
260
°C
TJunction
Junction temperature
150
°C
(1)
Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. These are stress ratings
only, which do not imply functional operation of the device at these or any other conditions beyond those indicated under Recommended
Operating Conditions. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
7.2 Storage Conditions
applicable before the DMD is installed in the final product
Tstg
DMD storage temperature
MSL
Moisture sensitivity level
MIN
MAX
UNIT
-65
150
°C
3
n/a
7.3 ESD Ratings
VALUE
V(ESD)
(1)
(2)
Electrostatic discharge
Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001 (1)
±2500
Charged-device model (CDM), per JEDEC specification JESD22C101 (2)
±1500
UNIT
V
JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.
JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.
7.4 Recommended Operating Conditions
over operating free-air temperature range (unless otherwise noted)
MIN
NOM
MAX
UNIT
Vcc
PLL supply voltage
PARAMETER
DEVICE
3.15
3.3
3.45
V
Vcp
Charge pump supply voltage
Vcc
5.25
V
TA
Ambient temperature
TJ
Junction temperature
LMX2492
-40
85
LMX2492-Q1
-40
125
LMX2492
-40
125
LMX2492-Q1
-40
135
°C
°C
7.5 Thermal Information
LMX2492 RTW
(WQFN )
24 PINS
THERMAL METRIC (1)
RθJA
Junction-to-ambient thermal resistance
39.4
RθJC
Junction-to-case thermal resistance
7.1
ψJB
Junction-to-board characterization parameter
20
(1)
4
UNIT
°C/W
For more information about traditional and new thermal metrics, see the IC Package Thermal Metrics application report, SPRA953.
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SNAS624B – MARCH 2014 – REVISED MAY 2015
7.6 Electrical Characteristics
(3.15 V ≤ Vcc ≤ 3.45 V. Vcc ≤Vcp ≤5.25 V. Typical values are at Vcc = Vcp = 3.3 V, 25 °C.
-40°C ≤ TA ≤ 85 °C for the LMX2492 and -40°C ≤ TA ≤ 125 °C for the LMX2492-Q1 ; except as specified.)
PARAMETER
CONDITIONS
All Vcc Pins
Icc
Current Consumption
Vcp Pin
IccPD
fOSCin
vOSCin
Current
Frequency for OSCin
terminal
Voltage for OSCin Pin (1)
Fpd = 100 MHz
50
Fpd = 200 MHz
55
Kpd = 0.1 mA
2
Kpd = 1.6 mA
10
Kpd = 3.1 mA
19
Frequency for FinPin
Power for Fin Pin
fPD
Phase Detector Frequency
PN10kHz
Normalized PLL 1/f
Noise (3)
ICPoutTRI
Charge Pump Leakage Tristate Leakage
OSC_DIFFR=0, Doubler Enabled
10
300
OSC_DIFFR=1, Doubler Disabled
10
1200
OSC_DIFFR=1, Doubler Enabled
10
600
LMX2492-Q1 Version Only
Single Ended XO
30 MHz ≤ fOSCin ≤ 100 MHz
0.24
Vcc-0.5
All Other Cases
0.5
Vcc-0.5
500
14000
MHz
-5
5
dBm
200
MHz
Charge Pump Mismatch
Normalized to 10 kHz offset for a 1 GHz
carrier.
(4)
Charge Pump Current
VCPout = Vcp / 2
(4)
MHz
Vpp
-227
dBc/Hz
-120
dBc/Hz
VCPout = Vcp / 2
nA
5%
0.1
…
CPG=31X
(1)
(2)
(3)
600
10
CPG=1X
ICPout
mA
3
(3)
PLL Figure of Merit
UNIT
10
Single-Ended Operation
PN1Hz
MAX
OSC_DIFFR=0, Doubler Disabled
(2)
pFin
TYP
45
POWERDOWN
fFin
ICPoutMM
MIN
Fpd = 10 MHz
mA
3.1
For optimal phase noise performance, a slew rate of at least 3 V/ns is recommended
Tested to 13.5 GHz, Guaranteed to 14 GHz by characterization
PLL Noise Metrics are measured with a clean OSCin signal with a high slew rate using a wide loop bandwidth. The noise metrics model
the PLL noise for an infinite loop bandwidth as:
PLL_Total = 10×log( 10PLL_Flat/10 + 10PLL_Flicker(Offset)/10)
PLL_Flat = PN1Hz + 20×log(N) + 10×log(Fpd/1Hz)
PLL_Flicker = PN10kHz - 10×log(Offset/10kHz) + 20×log(Fvco/1GHz)
Charge pump mismatch varies as a function of charge pump voltage. Consult typical performance characteristics to see this variation.
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Electrical Characteristics (continued)
(3.15 V ≤ Vcc ≤ 3.45 V. Vcc ≤Vcp ≤5.25 V. Typical values are at Vcc = Vcp = 3.3 V, 25 °C.
-40°C ≤ TA ≤ 85 °C for the LMX2492 and -40°C ≤ TA ≤ 125 °C for the LMX2492-Q1 ; except as specified.)
PARAMETER
CONDITIONS
MIN
TYP
0.8 x
Vcc
Vcc
MAX
UNIT
LOGIC OUTPUT TERMINALS (MUXout,TRIG1,TRIG2,MOD)
VOH
Output High Voltage
VOL
Output Low Voltage
V
0
0.2 x Vcc
V
V
LOGIC INPUT TERMINALS (CE,CLK,DATA,LE,MUXout,TRIG1,TRIG2,MOD)
VIH
Input High Voltage
1.4
Vcc
VIL
Input Low Voltage
0
0.6
V
IIH
Input Leakage
-5
5
uA
TCELOW
Chip enable Low Time
5
us
TCEHIGH
Chip enable High Time
5
us
1
7.7 Timing Requirements, Programming Interface (CLK, DATA, LE)
MIN
TCE
Clock To LE Low Time
TCS
TCH
NOM
MAX
UNIT
10
ns
Data to Clock Setup Time
4
ns
Data to Clock Hold Time
4
ns
TCWH
Clock Pulse Width High
10
ns
TCWL
Clock Pulse Width Low
10
ns
TCES
Enable to Clock Setup Time
10
ns
TEWH
Enable Pulse Width High
10
ns
MSB
DATA
R/W
LSB
A14
A13
A12
A11
A0
D7
D1
D0
CLK
tCES
tCS
tCH
tCWH
tCE
tCWL
LE
tEWH
Figure 1. Serial Data Input Timing
There are several other considerations for programming:
• 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 register to an actual counter.
• If no LE signal is given after the last data bit and the clock is kept toggling, then these bits will be read into
the next lower register. This eliminates the need to send the address each time.
• A slew rate of at least 30 V/us is recommended for the CLK, DATA, and LE signals
• Timing specifications also apply to readback. Readback can be done through the MUXout, TRIG1, TRIG2, or
MOD terminals.
6
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5
5
4
4
Charge Pump Current (mA)
Charge Pump Current (mA)
7.8 Typical Characteristics
3
2
1
0
±1
±2
±3
Kpd = 8x
Kpd = 16x
Kpd = 31x
±4
±5
0.0
0.3
0.6
0.9
1.2
1.5
1.8
2.1
2.4
2.7
Charge Pump Voltage (V)
3.0
3
2
1
0
±1
±2
±3
Kpd = 8x
Kpd = 16x
Kpd = 31x
±4
±5
3.3
0.0
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
4.5
5.0
Charge Pump Voltage (V)
C001
For a charge pump supply of 3.3 V, optimal performance is for a
typical charge pump output voltage between 0.5 and 2.8 volts.
Figure 2. Charge Pump Current for Vcp = 3.3 V
5.5
C002
For a charge pump supply voltage of 5 volts or higher, optimal
performance is typically for a charge pump output voltage between
0.5 and 4.5 volts.
Figure 3. Charge Pump Current for Vcp = 5.5 V
0
±5
Power (dBm)
±10
±15
±20
±25
±30
±35
±40
0
2
4
6
8
10
12
14
16
Frequency (GHz)
C001
Typical value of lowest power level as a function of frequency. Design to electrical specifications for input sensitivity, not typical performance
graphs.
Figure 4. Fin Input Sensitivity
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Typical Characteristics (continued)
±90
Theoretical 1/f
Theoretical Flat
Theoretical Model
Phase Noise (dBc/Hz)
±95
Measurement
±100
±105
±110
±115
±120
1k
10k
100k
1M
Offset (Hz)
C001
This plot is for a phase detector of 100 MHz, 2 MHz loop bandwidth, and VCO at 9600 MHz. However, the plot shown is the divide by 2 port
at 4800 MHz. The input was a 100 MHz Wenzel Oscillator. The model shows this phase noise has a figure of merit of -227 dBc/Hz and a
normalized 1/f noise of -120.5 dBc/Hz. The charge pump supply was 5 V and the charge pump output voltage was 1.34 V.
Figure 5. LMX2492/92-Q1 Phase Noise for Fpd =100 MHz, Fvco = 9600 MHz/2
8
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8 Detailed Description
8.1 Overview
The LMX2492/92-Q1 is a microwave PLL, consisting of a reference input and divider, high frequency input and
divider, charge pump, ramp generator, and other digital logic. The Vcc power supply pins run at a nominal 3.3
volts, while the charge pump supply pin, Vcp, operates anywhere from Vcc to 5 volts. The device is designed to
operate with an external loop filter and VCO. Modulation is achieved by manipulating the MASH engine.
8.2 Functional Block Diagram
GND (x3)
Vcc (x5)
Vcp
2X
OSCin
R Divider
(16 bit)
GND/OSCin*
Charge
Pump
Phase
Comp
Lock
Detect
Fin
N Divider
(18 bit)
Fin*
4/5
Prescaler
TRIG1
CE
CLK
DATA
LE
CPout
6'
Compensation
(24 bit)
MICROWIRE
Interface
Modulation
Generator
MUX
TRIG2
MOD
MUXout
8.3 Feature Description
8.3.1 OSCin Input
The reference can be applied in several ways. If using a differential input, this should be terminated differentially
with a 100 ohm resistance and AC coupled to the OSCin and GND/OSCin* terminals. If driving this single-ended,
then the GND/OSCin* terminal may be grounded, although better performance is attained by connecting the
GND/OSCin* terminal through a series resistance and capacitance to ground to match the OSCin terminal
impedance.
8.3.2 OSCin Doubler
The OSCin doubler allows the input signal to the OSCin to be doubled in order to have higher phase detector
frequencies. This works by clocking on both the rising and falling edges of the input signal, so it therefore
requires a 50% input duty cycle.
8.3.3 R Divider
The R counter is 16 bits divides the OSCin signal from 1 to 65535. If DIFF_R = 0, then any value can be chosen
in this range. If DIFF_R=1, then the divide is restricted to 2,4,8, and 16, but allows for higher OSCin frequencies.
8.3.4 PLL N Divider
The 16 bit N divider divides the signal at the Fin terminal down to the phase detector frequency. It contains a 4/5
prescaler that creates minimum divide restrictions, but allows the N value to increment in values of one.
Modulator Order
Minimum N
Divide
Integer Mode, 1st
Order Modulator
16
2nd Order Modulator
17
3rd Order Modulator
19
4th Order Modulator
25
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8.3.5 Fractional Circuitry
The fractional circuitry controls the N divider with delta sigma modulation that supports a programmable first,
second, third, and fourth order modulator. The fractional denominator is a fully programmable 24-bit denominator
that can support any value from 1,2,..., 224, with the exception when the device is running one of the ramps, and
in this case it is a fixed size of 224.
8.3.6 PLL Phase Detector and Charge Pump
The phase detector compares the outputs of the R and N dividers and generates a correction voltage
corresponding to the phase error. This voltage is converted to a correction current by the charge pump. The
phase detector frequency, fPD, can be calculated as follows: fPD = fOSCin × OSC_2X / R.
The charge pump supply voltage on this device, Vcp, can be either run at the Vcc voltage, or up to 5.25 volts in
order to get higher tuning voltages to present to the VCO.
8.3.7 External Loop Filter
The loop filter is external to the device and is application specific. Texas Instruments website has details on this
at www.ti.com.
8.3.8 Fastlock and Cycle Slip Reduction
The Fastlock™ and Cycle Slip Reduction features can be used to improved lock time. When the frequency is
changed, a timeout counter can be used to engage these features for a prescribed number of phase detector
cycles. During this time that the timeout counter is counting down, the device can be used to pull a terminal from
high impedance to ground switch in an extra resistor (R2pLF), change the charge pump current (FL_CPG), or
change the phase detector frequency. TRIG2 is recommended for switching the resistor with a setting of
TRIG2_MUX = Fastlock (2) and TRIG2_PIN = Inverted/Open Drain (5).
Charge
Pump
CPout
C2_LF
TRIG2
R2pLF
C1_LF
R2_LF
Fastlock
Control
Parameter
Normal Operation
Fastlock Operation
Charge Pump Gain
CPG
FL_CPG
Device Pin
(TRIG1, TRIG2, MOD, or MUXout)
High Impedance
Grounded
The resistor and the charge pump current are changed simultaneously so that the phase margin remains the
same while the loop bandwidth is by a factor of K as shown in the following table:
10
Parameter
Symbol
Calculation
Charge Pump Gain in Fastlock
FL_CPG
Typically use the highest value.
Loop Bandwidth Multiplier
K
K=sqrt(FL_CPG/CPG)
External Resistor
R2pLF
R2 / (K-1)
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Cycle slip reduction is another method that can also be used to speed up lock time by reducing cycle slipping.
Cycle slipping typically occurs when the phase detector frequency exceeds about 100x the loop bandwidth of the
PLL. Cycle slip reduction works in a different way than fastlock. To use this, the phase detector frequency is
decreased while the charge pump current is simultaneously increased by the same factor. Although the loop
bandwidth is unchanged, the ratio of the phase detector frequency to the loop bandwidth is, and this is helpful for
cases when the phase detector frequency is high. Because cycle slip reduction changes the phase detector rate,
it also impacts other things that are based on the phase detector rate, such as the fastlock timeout-counter and
ramping controls.
8.3.9 Lock Detect and Charge Pump Voltage Monitor
The LMX2492/92-Q1 offers two methods to determine if the PLL is in lock, charge pump voltage monitoring and
digital lock detect. These features can be used individually or in conjunction to give a reliable indication of when
the PLL is in lock. The output of this detection can be routed to the TRIG1, TRIG2, MOD, or MUXout terminals.
8.3.9.1 Charge Pump Voltage Monitor
The charge pump voltage monitor allows the user to set low (CMP_THR_LOW) and high (CMP_THR_HIGH)
thresholds for a comparator that monitors the charge pump output voltage.
Vcp
3.3 V
5.0 V
Threshold
Suggested Level
CPM_THR_LOW
= (Vthresh + 0.08) / 0.085
6 for 0.5V limit
CPM_THR_HIGH
= (Vthresh - 0.96) / 0.044
42 for 2.8V limit
CPM_THR_LOW
= (Vthresh + 0.056) / 0.137
4 for 0.5V limit
CPM_THR_HIGH
= (Vthresh -1.23) / 0.071
46 for 4.5V limit
8.3.9.2 Digital Lock Detect
Digital lock detect works by comparing the phase error as presented to the phase detector. If the phase error
plus the delay as specified by the PFD_DLY bit is outside the tolerance as specified by DLD_TOL, then this
comparison would be considered to be an error, otherwise passing. The DLD_ERR_CNT specifies how may
errors are necessary to cause the circuit to consider the PLL to be unlocked. The DLD_PASS_CNT specifies
how many passing comparisons are necessary to cause the PLL to be considered to be locked and also resets
the count for the errors. The DLD_TOL value should be set to no more than half of a phase detector period plus
the PFD_DLY value. The DLD_ERR_CNT and DLD_PASS_CNT values can be decreased to make the circuit
more sensitive. If the circuit is too sensitive, then chattering can occur and the DLD_ERR_CNT,
DLD_PASS_CNT, or DLD_TOL values should be increased.
Note that if the OSCin signal goes away and there is no noise or self-oscillation at the OSCin pin, then it is
possible for the digital lock detect to indicate a locked state when the PLL really is not in lock. If this is a concern,
then digital lock detect can be combined with charge pump voltage monitor to detect this situation..
8.3.10 FSK/PSK Modulation
Two level FSK or PSK modulation can be created whenever a trigger event, as defined by the FSK_TRIG field is
detected. This trigger can be defined as a transition on a terminal (TRIG1, TRIG2, MOD, or MUXout) or done
purely in software. The RAMP_PM_EN bit defines the modulation to be either FSK or PSK and the FSK_DEV
register determines the amount of the deviation. Remember that the FSK_DEV[32:0] field is programmed as the
2's complement of the actual desired FSK_DEV value. This modulation can be added to the modulation created
from the ramping functions as well.
RAMP_PM_EN
Modulation Type
Deviation
0
2 Level FSK
Fpd × FSK_DEV / 224
1
2 Level PSK
360° × FSK_DEV / 224
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8.3.11 Ramping Functions
The LMX2492/92-Q1 supports a broad and flexible class of FMCW modulation formed by up to 8 linear ramps.
When the ramping function is running, the denominator is fixed to a forced value of 224 = 16777216. The
waveform always starts at RAMP0 when the LSB of the PLL_N (R16) is written to. After it is set up, it will start at
the initial frequency and have piecewise linear frequency modulation that deviates from this initial frequency as
specified by the modulation. Each of the eight ramps can be individually programmed. Various settings are as
follows
Ramp Characteristic
Programming Field Name
Description
Ramp Length
RAMPx_LEN
RAMPx_DLY
The user programs the length of the ramp in phase detector cycles. If
RAMPx_DLY=1, then each count of RAMPx_LEN is actually two phase detector
cycles.
Ramp Slope
RAMPx_LEN
RAMPx_DLY
RAMPx_INC
The user does not directly program slope of the line, but rather this is done by
defining how long the ramp is and how much the fractional numerator is
increased per phase detector cycle. The value for RAMPx_INC is calculated by
taking the total expected increase in the frequency, expressed in terms of how
much the fractional numerator increases, and dividing it by RAMPx_LEN. The
value programmed into RAMPx_INC is actually the two's complement of the
desired mathematical value.
Trigger for Next Ramp
RAMPx_NEXT_TRIG
The event that triggers the next ramp can be defined to be the ramp finishing or
can wait for a trigger as defined by TRIG A, TRIG B, or TRIG C.
Next Ramp
RAMPx_NEXT
This sets the ramp that follows. Waveforms are constructed by defining a chain
ramp segments. To make the waveform repeat, make RAMPx_NEXT point to
the first ramp in the pattern.
Ramp Fastlock
RAMPx_FL
Ramp Flags
RAMPx_FLAG
This allows the ramp to use a different charge pump current or use Fastlock
This allows the ramp to set a flag that can be routed to external terminals to
trigger other devices.
8.3.11.1 Ramp Count
If it is desired that the ramping waveform keep repeating, then all that is needed is to make the RAMPx_NEXT of
the final ramp equal to the first ramp. This will run until the RAMP_EN bit is set to zero. If this is not desired, then
one can use the RAMP_COUNT to specify how may times the specified pattern is to repeat.
8.3.11.2 Ramp Comparators and Ramp Limits
The ramp comparators and ramp limits use programable thresholds to allow the device to detect whenever the
modulated waveform frequency crosses a limit as set by the user. The difference between these is that
comparators set a flag to alert the user while a ramp limits prevent the frequency from going beyond the
prescribed threshold. In either case, these thresholds are expressed by programming the
Extended_Fractional_Numerator.
Extended_Fractional_Numerator
=
Fractional_Numerator
+
(N-N*)
×
224
In the above, N is the PLL feedback value without ramping and N* is the instantaneous value during ramping.
The actual value programmed is the 2's complement of Extended_Fractional_Numerator.
Type
Ramp Limits
Ramp
Comparators
Programming Bit
Threshold
RAMP_LIMIT_LOW
Lower Limit
RAMP_LIMIT_HIGH
Upper Limit
RAMP_CMP0
RAMP_CMP1
For the ramp comparators, if the ramp is increasing and exceeds the value as specified
by RAMP_CMPx, then the flag will go high, otherwise it is low. If the ramp is decreasing
and goes below the value as specified by RAMP_CMPx, then the flag will go high,
otherwise it will be low.
8.3.12 Power on Reset (POR)
The power on reset circuitry sets all the registers to a default state when the device is powered up. This same
reset can be done by programming SWRST=1. In the programming section, the power on reset state is given for
all the programmable fields.
12
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8.4 Device Functional Modes
The two primary ways to use the LMX2492/92-Q1 are to run it to generate a set of frequencies
8.4.1 Continuous Frequency Generator
In this mode, the LMX2492/92-Q1 generates a single frequency that only changes when the N divider is
programmed to a new value. In this mode, the RAMP_EN bit is set to 0 and the ramping controls are not used.
The fractional denominator can be programmed to any value from 1 to 16777216. In this kind of application, the
PLL is tuned to different channels, but at each channel, the goal is to generate a stable fixed frequency.
8.4.1.1 Integer Mode Operation
In integer mode operation, the VCO frequency needs to be an integer multiple of the phase detector frequency.
This can be the case when the output frequency or frequencies are nicely related to the input frequency. As a
rule of thumb, if this an be done with a phase detector of as high as the lesser of 10 MHz or the OSCin
frequency, then this makes sense. To operate the device in integer mode, disable the fractional circuitry by
programming the fractional order (FRAC_ORDER) , dithering (FRAC_DITH), and numerator (FRAC_NUM) to
zero.
8.4.1.2 Fractional Mode Operation
In fractional mode, the output frequency does not need to be an integer multiple of the phase detector frequency.
This makes sense when the channel spacing is more narrow or the input and output frequencies are not nicely
related. There are several programmable controls for this such as the modulator order, fractional dithering,
fractional numerator, and fractional denominator. There are many trade-offs with choosing these, but here are
some guidelines
Parameter
Field Name
How to Choose
Fractional Numerator and
Denominator
FRAC_NUM
FRAC_DEN
The first step is to find the fractional denominator. To do this, find the frequency that
divides the phase detector frequency by the channel spacing. For instance, if the
output ranges from 5000 to 5050 in 5 MHz steps and the phase detector is 100
MHz, then the fractional denominator is 100 MHz/5 = 20. So for a an output of 5015
MHz, the N divider would be 50 + 3/20. In this case, the fractional numerator is 3
and the fractional denominator is 20. Sometimes when dithering is used, it makes
sense
to
express
this
as
a
larger
equivalent
fraction.
Note that if ramping is active, the fractional denominator is forced to 224.
Fractional Order
FRAC_ORDER
There are many trade-offs, but in general try either the 2nd or 3rd order modulator
as starting points. The 3rd order modulator may give lower main spurs, but may
generate others. Also if dithering is involved, it can generate phase noise.
Dithering
FRAC_DITH
Dithering can reduce some fractional spurs, but add noise. Consult application note
AN-1879 for more details on this.
8.4.2 Modulated Waveform Generator
In this mode, the device can generate a broad class of frequency sweeping waveforms. The user can specify up
to 8 linear segments in order to generate these waveforms. When the ramping function is running, the
denominator is fixed to a forced value of 224 = 16777216
In addition to the ramping functions, there is also the capability to use a terminal to add phase or frequency
modulation that can be done by itself or added on top of the waveforms created by the ramp generation
functions.
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8.5 Programming
8.5.1 Loading Registers
The device is programmed using several 24 bit registers. The first 16 bits of the register are the address,
followed by the next 8 bits of data. The user has the option to pull the LE terminal high after this data, or keep
sending data and it will apply this data to the next lower register. So instead of sending three registers of 24 bits
each, one could send a single 40 bit register with the 16 bits of address and 24 bits of data. For that matter, the
entire device could be programmed as a single register if desired.
8.6 Register Map
Registers are programmed in REVERSE order from highest to lowest. Registers NOT shown in this table or
marked as reserved can be written as all 0's unless otherwise stated. The POR value is the power on reset value
that is assigned when the device is powered up or the SWRST bit is asserted.
Table 1. Register Map
Register
14
0
0
1
0x1
D7
D6
D5
D4
D3
D2
D1
D0
POR
0
0
0
1
1
0
0
0
0x18
Reserved
0
0
0
0
0x00
2
0x2
3-15
0x3 - 0xF
Reserved
0
SWRST
POWERDOWN[1:0]
-
16
0x10
PLL_N[7:0]
0x64
17
0x11
18
0x12
19
0x13
FRAC_NUM[7:0]
0x00
20
0x14
FRAC_NUM[15:8]
0x00
21
0x15
FRAC_NUM[23:16]
0x00
22
0x16
FRAC_DEN[7:0]
0x00
23
0x17
FRAC_DEN[15:8]
0x00
24
0x18
FRAC_DEN[23:16]
0x00
25
0x19
PLL_R[7:0]
0x04
26
0x1A
PLL_R[15:8]
0x00
27
0x1B
0
28
0x1C
0
29
0x1D
30
0x1E
0
CPM_
FLAGL
CPM_THR_LOW[5:0]
0x0a
31
0x1F
0
CPM_
FLAGH
CPM_THR_HIGH[5:0]
0x32
32
0x20
FL_TOC[7:0]
33
0x21
DLD_PASS_CNT[7:0]
34
0x22
35
0x23
36
0x24
TRIG1_MUX[4:0]
TRIG1_PIN[2:0]
0x08
37
0x25
TRIG2_MUX[4:0]
TRIG2_PIN[2:0]
0x10
38
0x26
MOD_MUX[4:0]
MOD_PIN[2:0]
0x18
39
0x27
MUXout_MUX[4:0]
MUXout_PIN[2:0]
0x38
40-57
0x28-0x39
PLL_N[15:8]
0
FRAC_ORDER[2:0]
FL_CSR[1:0]
0
0x00
FRAC_DITHER[1:0]
CPPOL
FL_TOC[10:8]
MOD_
MUX[5]
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1
PLL_N[17:16]
PLL_R_
DIFF
PFD_DLY[1:0]
DLD_TOL[2:0]
0
OSC_2X
TRIG2
_MUX[5]
0x00
0x08
CPG[4:0]
0x00
FL_CPG[4:0]
0x00
0x00
0x0f
DLD_ERR_CNTR[4:0]
MUXout
_MUX[5]
0x00
TRIG1
_MUX[5]
0
Reserved
0x00
0
1
0x41
-
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Register Map (continued)
Table 1. Register Map (continued)
Register
58
D7
D6
D5
D4
D3
D2
D1
D0
POR
0
RAMP_
PM_EN
RAMP_
CLK
RAMP_EN
0x00
0x3A
RAMP_TRIG_A[3:0]
59
0x3B
RAMP_TRIG_C[3:0]
60
0x3C
RAMP_CMP0[7:0]
0x00
61
0x3D
RAMP_CMP0[15:8]
0x00
62
0x3E
RAMP_CMP0[23:16]
0x00
63
0x3F
RAMP_CMP0[31:24]
0x00
64
0x40
RAMP_CMP0_EN[7:0]
0x00
65
0x41
RAMP_CMP1[7:0]
0x00
66
0x42
RAMP_CMP1[15:8]
0x00
67
0x43
RAMP_CMP1[23:16]
0x00
68
0x44
RAMP_CMP1[31:24]
0x00
69
0x45
RAMP_CMP1_EN[7:0]
70
0x46
RAMP_
LIMH[32]
71
0x47
FSK_DEV[7:0]
0x00
72
0x48
FSK_DEV[15:8]
0x00
73
0x49
FSK_DEV[23:16]
0x00
74
0x4A
FSK_DEV[31:24]
0x00
75
0x4B
RAMP_LIMIT_LOW[7:0]
0x00
76
0x4C
RAMP_LIMIT_LOW[15:8]
0x00
77
0x4D
RAMP_LIMIT_LOW[23:16]
0x00
78
0x4E
RAMP_LIMIT_LOW[31:24]
0x00
79
0x4F
RAMP_LIMIT_HIGH[7:0]
0xff
80
0x50
RAMP_LIMIT_HIGH[15:8]
0xff
81
0x51
RAMP_LIMIT_HIGH[23:16]
0xff
82
0x52
RAMP_LIMIT_HIGH[31:24]
0xff
83
0x53
RAMP_COUNT[7:0]
0x00
84
0x54
85
0x55
0
FSK_TRIG[1:0]
RAMP_TRIG_INC[1:0]
RAMP_TRIG_B[3:0]
RAMP_
LIML[32]
RAMP_
AUTO
0x00
0x00
FSK_
DEV[32]
RAMP_
CMP1[32]
RAMP_COUNT[12:8]
Reserved
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RAMP_
CMP0[32]
0x08
0x00
0x00
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Register Map (continued)
Table 1. Register Map (continued)
Register
86
0x56
87
88
D6
D5
D4
D3
D2
D1
D0
POR
RAMP0_INC[7:0]
0x00
0x57
RAMP0_INC[15:8]
0x00
0x58
RAMP0_INC[23:16]
0x00
RAMP0_
DLY
RAMP0_
FL
89
0x59
90
0x5A
RAMP0_LEN[7:0]
91
0x5B
RAMP0_LEN[15:8]
92
0x5C
RAMP0_
NEXT_TRIG[1:0]
93
0x5D
RAMP1_INC[7:0]
0x00
94
0x5E
RAMP1_INC[15:8]
0x00
95
0x5F
RAMP1_INC[23:16]
0x00
96
0x60
97
0x61
RAMP1_LEN[7:0]
98
0x62
RAMP1_LEN[15:8]
99
0x63
RAMP1_
NEXT_TRIG[1:0]
100
0x64
101
102
RAMP0_NEXT[2:0]
RAMP1_
DLY
RAMP1_
FL
RAMP1_NEXT[2:0]
RAMP0_INC[29:24]
0x00
0x00
0x00
RAMP0_
RST
RAMP0_FLAG[1:0]
RAMP1_INC[29:24]
0x00
0x00
0x00
0x00
RAMP1_
RST
RAMP1_FLAG[1:0]
0x00
RAMP2_INC[7:0]
0x00
0x65
RAMP2_INC[15:8]
0x00
0x66
RAMP2_INC[23:16]
0x00
RAMP2
DLY
RAMP2_
FL
103
0x67
104
0x68
RAMP2_LEN[7:0]
105
0x69
RAMP2_LEN[15:8]
0x6A
RAMP2_
NEXT_TRIG[1:0]
106
RAMP2_NEXT[2:0]
RAMP2_INC[29:24]
0x00
0x00
0x00
RAMP2_
RST
RAMP2_FLAG[1:0]
0x00
107
0x6B
RAMP3_INC[7:0]
0x00
108
0x6C
RAMP3_INC[15:8]
0x00
109
0x6D
RAMP3_INC[23:16]
0x00
RAMP3_
DLY
RAMP3_
FL
110
0x6E
111
0x6F
RAMP3_LEN[7:0]
112
0x70
RAMP3_LEN[15:8]
0x71
RAMP3_
NEXT_TRIG[1:0]
113
16
D7
RAMP3_NEXT[2:0]
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RAMP3_INC[29:24]
0x00
0x00
0x00
RAMP3_
RST
RAMP3_FLAG[1:0]
0x00
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Register Map (continued)
Table 1. Register Map (continued)
Register
114
0x72
115
116
D7
D6
D5
D4
D3
D1
D0
POR
0x00
0x73
RAMP4_INC[15:8]
0x00
0x74
RAMP4_INC[23:16]
0x00
RAMP4_
DLY
RAMP4_
FL
117
0x75
118
0x76
RAMP4_LEN[7:0]
119
0x77
RAMP4_LEN[15:8]
0x78
RAMP4_
NEXT_TRIG[1:0]
120
D2
RAMP4_INC[7:0]
RAMP4_NEXT[2:0]
RAMP4_INC[29:24]
0x00
0x00
0x00
RAMP4_
RST
RAMP4_FLAG[1:0]
0x00
121
0x79
RAMP5_INC[7:0]
0x00
122
0x7A
RAMP5_INC[15:8]
0x00
123
0x7B
RAMP5_INC[23:16]
0x00
124
0x7C
125
0x7D
RAMP5_LEN[7:0]
126
0x7E
RAMP5_LEN[15:8]
127
0x7F
RAMP5_
NEXT_TRIG[1:0]
128
0x80
129
130
RAMP5_
DLY
RAMP5_
FL
RAMP5_NEXT[2:0]
RAMP5_INC[29:24]
0x00
0x00
0x00
RAMP5_
RST
RAMP5_FLAG[1:0]
0x00
RAMP6_INC[7:0]
0x00
0x81
RAMP6_INC[15:8]
0x00
0x82
RAMP6_INC[23:16]
0x00
RAMP6_
DLY
RAMP6_
FL
131
0x83
132
0x84
RAMP6_LEN[7:0]
133
0x85
RAMP6_LEN[15:8]
134
0x86
RAMP6_
NEXT_TRIG[1:0]
135
0x87
RAMP7_INC[7:0]
0x00
136
0x88
RAMP7_INC[15:8]
0x00
137
0x89
RAMP7_INC[23:16]
0x00
RAMP6_NEXT[2:0]
RAMP7_
DLY
RAMP7_
FL
RAMP6_INC[29:24]
138
0x8A
139
0x8B
RAMP7_LEN[7:0]
140
0x8C
RAMP7_LEN[15:8]
141
0x8D
RAMP7_
NEXT_TRIG[1:0]
142-32767
0x8E0x7fff
RAMP7_NEXT[2:0]
0x00
0x00
0x00
RAMP6_
RST
RAMP6_FLAG[1:0]
RAMP7_INC[29:24]
0x00
0x00
0x00
0x00
RAMP7_
RST
Reserved
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0x00
0x00
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8.7 Register Field Descriptions
The following sections go through all the programmable fields and their states. Additional information is also
available in the applications and feature descriptions sections as well. The POR column is the power on reset
state that this field assumes if not programmed.
8.7.1 POWERDOWN and Reset Fields
Table 2. POWERDOWN and Reset Fields
Field
POWERDOWN
[1:0]
SWRST
18
Location
R2[1:0]
R2[2]
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POR
0
0
Description and States
POWERDOWN Control
Software Reset. Setting this bit sets all
registers to their POR default values.
Value
POWERDOWN State
0
POWERDOWN, ignore CE
1
Power Up, ignore CE
2
Power State Defined by CE
terminal state
3
Reserved
Value
Reset State
0
Normal Operation
1
Register Reset
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8.7.2 Dividers and Fractional Controls
Table 3. Dividers and Fractional Controls
Field
Location
POR
Description and States
PLL_N
[17:0]
R18[1] to
R16[0]
16
Feedback N counter Divide value. Minimum count is 16. Maximum is 262132. Writing of
the register R16 begins any ramp execution when RAMP_EN=1.
Value
FRAC_ DITHER
[1:0]
FRAC_ ORDER
[2:0]
R18[3:2]
R18[6:4]
0
Dither used by the fractional modulator
0
Fractional Modulator order
Dither
0
Weak
1
Medium
2
Strong
3
Disabled
Value
Modulator Order
0
Integer Mode
1
1st Order Modulator
2
2nd Order Modulator
3
3rd Order Modulator
4
4th Order Modulator
5-7
Reserved
FRAC_NUM
[23:0]
R21[7] to
R19[0]
0
Fractional Numerator. This value should be less than or equal to the fractional
denominator.
FRAC_DEN
[23:0]
R24[7] to
R22[0]
0
Fractional Denominator. If the RAMP_EN=1, this field is ignored and the denominator is
fixed to 224.
PLL_R
[15:0]
R26[7] to
R25[0]
1
Reference Divider value. Selecting 1 will bypass counter.
0
Enables the Doubler before the Reference
divider
OSC_2X
PLL_R _DIFF
PFD_DLY
[1:0]
CPG
[4:0]
CPPOL
R27[0]
R27[2]
R27[4:3]
R28[4:0]
R28[5]
Enables the Differential R counter.
This allows for higher OSCin frequencies,
but restricts PLL_R to divides of 2,4,8 or
16.
0
Sets the charge pump minimum pulse
width. This could potentially be a trade-off
between fractional spurs and phase noise.
Setting 1 is recommended for general use.
1
0
Charge pump gain
Charge
Pump
Polarity
Positive is for a positive slope VCO
characteristic, negative otherwise.
0
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Value
Doubler
0
Disabled
1
Enabled
Value
R Divider
0
Single-Ended
1
Differential
Value
Pulse Width
0
Reserved
1
860 ps
2
1200 ps
3
1500 ps
Value
Charge Pump State
0
Tri-State
1
100 uA
2
200 uA
…
…
31
3100 uA
Value
Charge Pump Polarity
0
Negative
1
Positive
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8.7.2.1 Speed Up Controls (Cycle Slip Reduction and Fastlock)
Table 4. FastLock and Cycle Slip Reduction
Field
FL_ CSR
[1:0]
FL_ CPG
[4:0]
FL_ TOC
[10:0]
20
Location
R27[6:5]
R29[4:0]
R29[7:5]
and
R32[7:0]
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POR
0
0
0
Description and States
Cycle Slip Reduction (CSR) reduces the
phase detector frequency by multiplying
both the R and N counters by the CSR
value while either the FastLock Timer is
counting or the RAMPx_FL=1 and the part
is ramping. Care must be taken that the R
and N divides remain inside the range of
the counters. Cycle slip reduction is
generally
not
recommended
during
ramping.
Charge pump gain only when Fast Lock
Timer is counting down or a ramp is
running with RAMPx_FL=1
Fast Lock Timer. This counter starts
counting when the user writes the
PLL_N(Register R16). During this time the
FL_CPG gain is sent to the charge pump,
and the FL_CSR shifts the R and N
counters if enabled. When the counter
terminates, the normal CPG is presented
and the CSR undo’s the shifts to give a
normal PFD frequency.
Value
CSR Value
0
Disabled
1
x2
2
x 4.
3
Reserved
Value
Fastlock Charge Pump Gain
0
Tri-State
1
100 uA
2
200 uA
…
…
31
3100 uA
Value
Fastlock Timer Value
0
Disabled
1
1 x 32 = 32
...
2047
2047 x 32 = 65504
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8.8 Lock Detect and Charge Pump Monitoring
Table 5. Lock Detect and Charge Pump Monitor
Field
CPM_THR _LOW
[5:0]
CPM_FLAGL
CPM_THR _HIGH
[5:0]
CPM_FLAGH
Location
R30[5:0]
R30[6]
R31[5:0]
R31[6]
POR
0x0A
Description and States
Charge pump voltage low threshold value.
When the charge pump voltage is below
this threshold, the LD goes low.
This is a read only bit.
Low indicates the charge pump voltage is
below the minimum threshold.
-
0x32
Charge pump voltage high threshold value.
When the charge pump voltage is above
this threshold, the LD goes low.
This
is
a
read
only
bit.
Charge pump voltage high comparator
reading. High indicates the charge pump
voltage is above the maximum threshold.
-
Value
Threshold
0
Lowest
…
…
63
Highest
Value
Flag Indication
0
Charge pump is below
CPM_THR_LOW threshold
1
Charge pump is above
CPM_THR_LOW threshold
Value
Threshold
0
Lowest
…
…
63
Highest
Value
Threshold
0
Charge pump is below
CPM_THR_HIGH threshold
1
Charge pump is above
CPM_THR_HIGH threshold
DLD_ PASS_CNT
[7:0]
R33[7:0]
0xff
Digital Lock Detect Filter amount. There must be at least DLD_PASS_CNT good edges
and less than DLD_ERR edges before the DLD is considered in lock. Making this number
smaller will speed the detection of lock, but also will allow a higher chance of DLD chatter.
DLD_ ERR_CNT
[4:0]
R34[4:0]
0
Digital Lock Detect error count. This is the maximum number of errors greater than
DLD_TOL that are allowed before DLD is de-asserted. Although the default is 0, the
recommended value is 4.
Value
DLD _TOL
[2:0]
R34[7:5]
Digital Lock detect edge window. If both N
and R edges are within this window, it is
considered a “good” edge. Edges that are
farther apart in time are considered “error”
edges. Window choice depends on phase
detector frequency, charge pump minimum
pulse width, fractional modulator order and
the users desired margin.
0
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Window and Fpd Frequency
0
1 ns (Fpd > 130 MHz)
1
1.7 ns (80 MHz , Fpd ≤ 130
MHz)
2
3 ns (60 MHz , Fpd ≤ 80 MHz)
3
6 ns (45 MHz , Fpd ≤ 60 MHz)
4
10 ns (30 MHz < Fpd ≤ 45
MHz)
5
18 ns ( Fpd ≤ 30 MHz)
6 and 7
Reserved
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8.9 TRIG1,TRIG2,MOD, and MUXout Pins
Table 6. TRIG1, TRIG2, MOD, and MUXout Terminal States
Field
TRIG1 _PIN
[2:0]
R36[2:0]
POR
R37[2:0]
0
MOD_ _PIN
[2:0]
R38[2:0]
0
R39[2:0]
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Description and States
0
TRIG2 _PIN
[2:0]
MUXout_ _PIN
[2:0]
22
Location
This is the terminal drive state for the
TRIG1, TRIG2, MOD, and MUXout Pins
0
Value
Pin Drive State
0
TRISTATE (default)
1
Open Drain Output
2
Pullup / Pulldown Output
3
Reserved
4
GND
5
Inverted Open Drain Output
6
Inverted Pullup / Pulldown
Output
7
Input
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Table 7. TRIG1, TRIG2, MOD, and MUXout Selections
Field
Location
POR
Description and States
Value
TRIG1_MUX
[5:0]
TRIG2_MUX
[5:0]
MOD_MUX
[5:0]
MUXout_MUX
[5:0]
R36[7:3],
R37.3
R36[7:3],
R35.3
R37[7:3],
R35.4
R38[7:3],
R35.7
These fields control what signal is muxed
to or from the TRIG1,TRIG2, MOD, and
MUXout
pins.
Some of the abbreviations used are:
COMP0, COMP1: Comparators 0 and 1
LD, DLD: Lock Detect, Digital Lock Detect
CPM:
Charge
Pump
Monitor
CPG:
Charge
Pump
Gain
CPUP:
Charge
Pump
Up
Pulse
CPDN: Charge Pump Down Pulse
1
2
3
7
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MUX State
0
GND
1
Input TRIG1
2
Input TRIG2
3
Input MOD
4
Output TRIG1 after
synchronizer
5
Output TRIG2 after
synchronizer
6
Output MOD after
synchronizer
7
Output Read back
8
Output CMP0
9
Output CMP1
10
Output LD (DLD good AND
CPM good)
11
Output DLD
12
Output CPMON good
13
Output CPMON too High
14
Output CPMON too low
15
Output RAMP LIMIT
EXCEEDED
16
Output R Divide/2
17
Output R Divide/4
18
Output N Divide/2
19
Output N Divide/4
20
Reserved
21
Reserved
22
Output CMP0RAMP
23
Output CMP1RAMP
24
Reserved
25
Reserved
26
Reserved
27
Reserved
28
Output Faslock
29
Output CPG from RAMP
30
Output Flag0 from RAMP
31
Output Flag1 from RAMP
32
Output TRIGA
33
Output TRIGB
34
Output TRIGC
35
Output R Divide
36
Output CPUP
37
Output CPDN
38
Output RAMP_CNT Finished
39 to 63
Reserved
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8.10 Ramping Functions
Table 8. Ramping Functions
Field
RAMP_EN
RAMP_CLK
RAMP_PM_EN
RAMP_TRIGA
[3:0]
RAMP_TRIGB
[3:0]
RAMP_TRIGC
[3:0]
R58[0]
R58[1]
R58[2]
R58[7:4]
R59[3:0]
R59[7:4]
POR
0
0
0
0
Description and States
Enables the RAMP functions. When this bit
is set, the Fractional Denominator is fixed
to 224. RAMP execution begins at RAMP0
upon the PLL_N[7:0] write. The Ramp
should be set up before RAMP_EN is set.
Value
Ramp
0
Disabled
1
Enabled
RAMP clock input source. The ramp can
be clocked by either the phase detector
clock or the MOD terminal based on this
selection.
Value
Source
0
Phase Detector
Phase modulation enable.
Trigger A,B, and C Sources
1
MOD Terminal
Value
Modulation Type
0
Frequency Modulation
1
Phase Modulation
Value
Source
0
Never Triggers (default)
1
TRIG1 terminal rising edge
2
TRIG2 terminal rising edge
3
MOD terminal rising edge
4
DLD Rising Edge
5
CMP0 detected (level)
6
RAMPx_CPG Rising edge
7
RAMPx_FLAG0 Rising edge
8
Always Triggered (level)
9
TRIG1 terminal falling edge
10
TRIG2 terminal falling edge
11
MOD terminal falling edge
12
DLD Falling Edge
13
CMP1 detected (level)
14
RAMPx_CPG Falling edge
15
RAMPx_FLAG0 Falling edge
RAMP_CMP0
[32:0]
R70[0],
R63[7] to
R60[0]
0
Twos compliment of Ramp Comparator 0 value. Be aware of that the MSB is in Register
R70.
RAMP_CMP0_EN
[7:0]
R64[7:0]
0
Comparator 0 is active during each RAMP corresponding to the bit. Place a 1 for ramps it
is active in and 0 for ramps it should be ignored. RAMP0 corresponds to R64[0], RAMP7
corresponds to R64[7]
RAMP_CMP1
[32:0]
R70[1],
R68[7] to
R65[0]
0
Twos compliment of Ramp Comparator 1 value. Be aware of that the MSB is in Register
R70.
RAMP_CMP1_EN
[7:0]
R69[7:0]
0
Comparator 1 is active during each RAMP corresponding to the bit. Place a 1 for ramps it
is active in and 0 for ramps it should be ignored. RAMP0 corresponds to R64[0], RAMP7
corresponds to R64[7].
FSK_TRIG
[1:0]
FSK_DEV
[32:0]
24
Location
R76[4] to
R75[3]
R70[2],
R74[7] to
R71[0]
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0
0
Deviation trigger source. When this trigger
source specified is active, the FSK_DEV
value is applied.
Value
Trigger
0
Always Triggered
1
Trigger A
2
Trigger B
3
Trigger C
Twos compliment of the deviation value for frequency modulation and phase modulation.
This value should be written with 0 when not used. Be aware that the MSB is in Register
R70.
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Ramping Functions (continued)
Table 8. Ramping Functions (continued)
Field
Location
POR
Description and States
RAMP_LIMIT_LOW
[32:0]
R70[3],
R78[7] to
75[0]
Twos compliment of the ramp lower limit that the ramp can not go below . The ramp limit
0x000 occurs before any deviation values are included. Care must be taken if the deviation is
00000 used and the ramp limit must be set appropriately. Be aware that the MSB is in Register
R70.
RAMP_LIMIT_HIGH
[32:0]
R70[4],
R82[7] to
79.0[0]
Twos compliment of the ramp higher limit that the ramp can not go above. The ramp limit
0xfffffff occurs before any deviation values are included. Care must be taken if the deviation is
f
used and the ramp limit must be set appropriately. Be aware that the MSB is in Register
R70.
RAMP_COUNT
[12:0]
R84[4] to
R83[0]
RAMP_AUTO
RAMP_TRIG_INC
[1:0]
R84[5]
R84[7:6]
Number of RAMPs that will be executed before a trigger or ramp enable is brought down.
Load zero if this feature is not used. Counter is automatically reset when RAMP_EN goes
from 0 to 1.
0
Automatically clear RAMP_EN
RAMP Count hits terminal count.
0
when
Increment Trigger source for RAMP
Counter. To disable ramp counter, load a
count value of 0.
0
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Value
Ramp
0
RAMP_EN unaffected by ramp
counter (default)
1
RAMP_EN automatically
brought low when ramp
counter terminal counts
Value
Source
0
Increments occur on each
ramp transition
1
Increment occurs on trigA
2
Increment occurs on trigB
3
Increment occurs on trigC
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8.11 Individual Ramp Controls
These bits apply for all eight ramps. For the field names, x can be 0,1,2,3,4,5,6, or 7.
Table 9. Individual Ramp Controls
Field
Location
POR
Description and States
RAMPx
_INC[29:0]
Varies
0
Signed ramp increment.
RAMPx _FL
Varies
0
RAMPx
_DLY
RAMPx
_LEN
RAMPx
_FLAG[1:0]
RAMP0
_RST
RAMPx_
NEXT
_TRIG
[1:0]
RAMP0
_NEXT[2:0]
26
Varies
Varies
Varies
Varies
Varies
Varies
0
0
0
0
0
This enables fastlock and cycle slip reduction for ramp x.
During this ramp, each increment takes 2 PFD cycles per
LEN clock instead of the normal 1 PFD cycle. Slows the
ramp by a factor of 2.
Value
CPG
0
Disabled
1
Enabled
Value
Clocks
0
1 PFD clock per RAMP
tick.(default)
1
2 PFD clocks per RAMP
tick.
Number of PFD clocks (if DLY is 0) to continue to increment RAMP. 1=>1 cycle, 2=>2 etc. Maximum of
65536 cycles.
General purpose FLAGS sent out of RAMP.
Forces a clear of the ramp accumulator. This is used to
erase any accumulator creep that can occur depending on
how the ramps are defined. Should be done at the start of a
ramp pattern.
Determines what event is necessary to cause the state
machine to go to the next ramp. It can be set to when the
RAMPx_LEN counter reaches zero or one of the events for
Triggers A,B, or C.
0
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Value
Flag
0
Both FLAG1 and FLAG0
are zero. (default)
1
FLAG0 is set, FLAG1 is
clear
2
FLAG0 is clear, FLAG1 is
set
3
Both FLAG0 and FLAG1
are set.
Value
Reset
0
Disabled
1
Enabled
Value
Operation
0
RAMPx_LEN
1
TRIG_A
2
TRIG_B
3
TRIG_C
The next RAMP to execute when the length counter times out
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9 Applications and Implementation
NOTE
Information in the following applications sections is not part of the TI component
specification, and TI does not warrant its accuracy or completeness. TI’s customers are
responsible for determining suitability of components for their purposes. Customers should
validate and test their design implementation to confirm system functionality.
9.1 Application Information
The LMX2492/92-Q1 can be used in a broad class of applications such as generating a single frequency for a
high frequency clock, generating a tunable range of frequencies, or generating swept waveforms that can be
used in applications such as radar.
9.2 Typical Applications
The following schematic is an example of hat could be used in a typical application.
3.3 or 5 V
R3_LF
100 nF
C2_LF
C1_LF
C3_LF
3.3 V
R2_LF
GND
4
19
Vcc
3
20
TRIG1
GND
21
TRIG2
2
22
Vcp
GND
23
Rset
1
24
CPout
100 nF
3.3 V
Vcc
MUXOUT
18
17
100 nF
18 :
LE
16
Fin
DATA
15
5
Fin*
CLK
14
6
Vcc
CE
13
10 pF
68 :
OSCin
GND/OSCin*
GND
MOD
3.3 V
10 pF
Vcc
36 :
Vcc
To
Circuit
18 :
7
8
9
10
11
12
51 :
100 nF
3.3 V
3.3 V
18 :
100 nF
100 nF
68 :
18 :
9.2.1 Design Requirements
For these examples, it will be assumed that there is a 100 MHz input signal and the output frequency is between
9400 and 9800 MHz with various modulated waveforms.
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Typical Applications (continued)
Parameter
Symbol
Value
Input Frequency
OSCin
100 MHz
Comments
Phase Detector
Frequency
Fpd
100 MHz
There are many possibilities, but this choice gives
good performance and saves a little current (as
shown in the electrical specifications).
9400 - 9800 MHz (Simple Chirp)
VCO Frequency
Fvco
VCO Gain
Kvco
In the different examples, the VCO frequency is
actually changing. However, the same loop filter
9500 - 9625 MHz (Complex Triggered design can be used for all three.
Ramp
9400 - 9800 (Flattened Ramp)
200 MHz/V
This parameter has nothing to do with the
LMX2492/92-Q1, but is rather set by the external
VCO choice.
9.2.2 Detailed Design Procedure
The first step is to calculate the reference divider (PLL_R) and feedback divider (PLL_N) values as shown in the
table that follows.
Parameter
Symbol and Calculations
Value
Comments
Average
VCO Frequency
FvcoAvg
= (FvcoMax + FvcoMin)/2
9600 MHz
To design a loop filter, one designs for a fixed VCO
value, although it is understood that the VCO will
tune around. This typical value is usually chosen as
the average VCO frequency.
VCO Gain
Kvco
200 MHz/V
This parameter has nothing to do with the
LMX2492/92-Q1, but is rather set by the external
VCO choice. In this case, it was the RFMD1843
VCO.
PLL Loop Bandwidth
BW
380 kHz
This bandwidth is very wide to allow the VCO
frequency to be modulated.
Charge Pump Gain
CPG
3.1 mA
Using the larger gain allows a wider loop bandwidth
and gives good phase performance.
R Divider
PLL_R
= OSCin / Fpd
1
This value is calculated from previous values.
N Divider
PLL_N
= Fvco / Fpd
96
This value is calculated from previous values.
Loop Filter
Components
C1_LF
68 pF
C2_LF
3.9 nF
C3_LF
150 pF
R2_LF
390 ohm
R3_LF
390 ohm
These were calculated by TI design tools.
Once a loop filter bandwidth is chosen, the external loop filter components of C1_LF, C2_LF, C3_LF, R2_LF, and
R3_LF can be calculated with a tool such as the Clock Architect tool available at www.ti.com. It is also highly
recommended to look at the EVM instructions. The CodeLoader software is an excellent starting point and
example to see how to program this device.
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9.2.3 Application Performance Plot - Sawtooth Waveform Example
Using the above design, it can be programmed to generate a sawtooth waveform with the following paramters.
Parameter
Symbol
Value
Ramp Duration
ΔT
100 uS
VCO Frequency
Fvco
9400 - 9800 MHz
Range
ΔF
9400 - 9800 MHz = 400 MHz Change
tRAMP0t
tRAMP0t
tRAMP0t
tRAMP0t
Because we want the ramp length to be 100 us, this works out to 10,000 phase detector cycles which means
that RAMP0_LEN=10000. To change 400 MHz, we know that each one of the 10000 steps is 40 kHz. Given the
fractional denominator is 224 = 16777216 and the phase detector frequency is 100 MHz, this implies that the
fractional numerator at the end of the ramp will be 6711. However, since this 6711 number is not exact (closer to
6718.8864), the ramp will creep if we do not reset it. Therefore, we set reset the ramp. After the ramp finishes,
we want to start with the same ramp, so RAMP0_NEXT is RAMP0. The results of this analysis are in the table
below:
RAMP
RAMP0_LEN
RAMP0_INC
RAMP0_NEXT
RAMP0_RST
RAMP0
ΔT × Fpd = 100 us / 100 MHz
= 10000
(ΔF / Fpd) /RAMP0_LEN × 224
= (400/100)/10000 ×16777216 = 6711
0
1
The actual measured waveform for this is shown in the following figure. Note that the frequency that was actually
measured was from the divide by two output of the VCO and therefore the measured frequency was half of the
actual frequency presented to the PLL. This ramping waveform does show some undershoot as the frequency
rapidly returns from 9800 MHz ( 4900 MHz on the plot) to 9400 MHz (4700 MHz on the plot). This undershoot
can be mitigated by adding additional ramps.
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9.2.4 Application Performance Plot - Flat Top Triangle Waveform
Now consider pattern as shown below. The ramp is sometimes used because it can better account for Doppler
Shift. The purpose for making the top and bottom portions flat is to help reduce the impact of the PLL
overshooting and undershooting in order to make the sloped ramped portions more linear.
Parameter
Ramp Duration
Range
Symbol
Value
ΔT0
10 uS
ΔT1
90 uS
ΔT2
10 uS
ΔT3
90 uS
ΔF0
0
ΔF1
400 MHz
ΔF2
0
ΔF3
-400 MHz
tRAMP1t
RAMP0
tRAMP1t
RAMP2
RAMP0
RAMP
RAMPx_LEN
RAMPx_INC
RAMP0
10 us/ 100 MHz
=1000
0
RAMP2
RAMPx_NEXT
RAMPx_RST
1
1
24
RAMP1
90 us / 100 MHz
=9000
(ΔF / Fpd) /RAMP1_LEN × 2
= (400/100)/9000 ×16777216 =
7457
2
0
RAMP2
10 us/ 100 MHz
=1000
0
3
0
90 us / 100 MHz
=9000
(ΔF / Fpd) /RAMP1_LEN × 224
= (-400/100)/9000 ×16777216 =
-7457
Program in 2's complement of 7457
= 230-7457 = 1073734367
0
0
RAMP3
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The actual measured waveform for this is shown in the following figure. Note that the frequency that was actually
measured was from the divide by two output of the VCO and therefore the measured frequency was half of the
actual frequency presented to the PLL. The flattened top and bottom of this triangle wave help mitigate the
overshoot and undersoot in the frequency.
The actual measured waveform for this is shown in the following figure. Note that the frequency that was actually
measured was from the divide by two output of the VCO and therefore the measured frequency was half of the
actual frequency presented to the PLL. The flattened top and bottom of this triangle wave help mitigate the
overshoot and undersoot in the frequency.
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9.2.5 Applications Performance Plot -- Complex Triggered Ramp
In this example, the modulation is not started until a trigger pulse from the MOD terminal goes high. Assume a
phase detector frequency of 100 MHz and we RAMP1 to be 60 us and ramps 2,3,and 4 to be 12 us each. We
set the next trigger for RAMP0 to be trigger A and define trigger A to be the MOD terminal. Then we configure as
follows:
MOD
Frequency
9.800 GHz
Increased Charge Pump Gain
Increased Charge Pump Gain
9.800 GHz
9.400 GHz
9.725 GHz
9.600 GHz
FLAG0
TRIG1 Output as Loop Filter Switch 1
FLAG1
TRIG2 Output as Loop Filter Switch 2
'T0
'T2
'T1
'T3
'T4
'T1
'T2
'T3
'T4
Figure 6. Complex Triggered Ramp Example
RAMP
RAMPx
_LEN
RAMPx_
INC
RAMPx_FL
RAMPx
_NEXT
RAMPx_FLAG
RAMPx_
NEXT_TRIG
RAMPx_RS
T
RAMP0
1
0
0
1
FLAG0 and
FLAG1
TRIG A
1
RAMP1
6000
1073730639
0
2
FLAG0 and
FLAG1
TOC Timeout
1
RAMP2
1200
27963
1
3
Disabled
TOC Timeout
0
RAMP3
1200
17476
0
4
FLAG1
TOC Timeout
0
1
FLAG0 and
FLAG1
TOC Timeout
0
RAMP4
32
1200
Submit Documentation Feedback
10486
0
Copyright © 2014–2015, Texas Instruments Incorporated
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LMX2492, LMX2492-Q1
www.ti.com
SNAS624B – MARCH 2014 – REVISED MAY 2015
The actual measured waveform for this is shown in the following figure. Note that the frequency that was actually
measured was from the divide by two output of the VCO and therefore the measured frequency was half of the
actual frequency presented to the PLL. The flattened top and bottom of this triangle wave help mitigate the
overshoot and undersoot in the frequency.
Figure 7. Actual Measurement for Complex Triggered Ramp
10 Power Supply Recommendations
For power supplies, it is recommended to place 100 nF close to each of the power supply pins. If fractional spurs
are a large concern, using a ferrite bead to each of these power supply pins can reduce spurs to a small degree.
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11 Layout
11.1 Layout Guidelines
For layout examples, the EVM instructions are the most comprehensive document. In general, the layout
guidelines are similar to most other PLL devices. For the high frequency Fin pin, it is recommended to use 0402
components and match the trace width to these pad sizes. Also the same needs to be done on the Fin* pin. If
layout is easier to route the signal to Fin* instead of Fin, then this is acceptable as well.
11.2 Layout Example
34
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LMX2492, LMX2492-Q1
www.ti.com
SNAS624B – MARCH 2014 – REVISED MAY 2015
12 Device and Documentation Support
12.1 Device Support
12.1.1 Development Support
Texas Instruments has several software tools to aid in the development process including CodeLoder for
programming, Clock Design Tool for Loop filter design and phase noise/spur simulation, and the Clock Architect.
All these tools are available at www.ti.com.
12.2 Documentation Support
12.2.1 Related Documentation
For the avid reader, the following resources are available at www.ti.com.
Application Note 1879 -- Fractional N Frequency Synthesis
PLL Performance, Simulation, and Design -- by Dean Banerjee
12.3 Related Links
The table below lists quick access links. Categories include technical documents, support and community
resources, tools and software, and quick access to sample or buy.
Table 10. Related Links
PARTS
PRODUCT FOLDER
SAMPLE and BUY
TECHNICAL
DOCUMENTS
TOOLS and
SOFTWARE
SUPPORT and
COMMUNITY
LMX2492
Click here
Click here
Click here
Click here
Click here
LMX2492-Q1
Click here
Click here
Click here
Click here
Click here
12.4 Community Resources
The following links connect to TI community resources. Linked contents are provided "AS IS" by the respective
contributors. They do not constitute TI specifications and do not necessarily reflect TI's views; see TI's Terms of
Use.
TI E2E™ Online Community TI's Engineer-to-Engineer (E2E) Community. Created to foster collaboration
among engineers. At e2e.ti.com, you can ask questions, share knowledge, explore ideas and help
solve problems with fellow engineers.
Design Support TI's Design Support Quickly find helpful E2E forums along with design support tools and
contact information for technical support.
12.5 Trademarks
E2E is a trademark of Texas Instruments.
All other trademarks are the property of their respective owners.
12.6 Electrostatic Discharge Caution
These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam
during storage or handling to prevent electrostatic damage to the MOS gates.
12.7 Glossary
SLYZ022 — TI Glossary.
This glossary lists and explains terms, acronyms, and definitions.
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13 Mechanical, Packaging, and Orderable Information
The following pages include mechanical, packaging, and orderable information. This information is the most
current data available for the designated devices. This data is subject to change without notice and revision of
this document. For browser-based versions of this data sheet, refer to the left-hand navigation.
36
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PACKAGE OPTION ADDENDUM
www.ti.com
27-May-2015
PACKAGING INFORMATION
Orderable Device
Status
(1)
Package Type Package Pins Package
Drawing
Qty
Eco Plan
Lead/Ball Finish
MSL Peak Temp
(2)
(6)
(3)
Op Temp (°C)
Device Marking
(4/5)
LMX2492QRTWRQ1
ACTIVE
WQFN
RTW
24
1000
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 125
X2492Q
LMX2492QRTWTQ1
ACTIVE
WQFN
RTW
24
250
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 125
X2492Q
LMX2492RTWR
ACTIVE
WQFN
RTW
24
1000
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 85
X2492
LMX2492RTWT
ACTIVE
WQFN
RTW
24
250
Green (RoHS
& no Sb/Br)
CU SN
Level-3-260C-168 HR
-40 to 85
X2492
(1)
The marketing status values are defined as follows:
ACTIVE: Product device recommended for new designs.
LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect.
NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design.
PREVIEW: Device has been announced but is not in production. Samples may or may not be available.
OBSOLETE: TI has discontinued the production of the device.
(2)
Eco Plan - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability
information and additional product content details.
TBD: The Pb-Free/Green conversion plan has not been defined.
Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that
lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes.
Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between
the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.
Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight
in homogeneous material)
(3)
MSL, Peak Temp. - The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.
(4)
There may be additional marking, which relates to the logo, the lot trace code information, or the environmental category on the device.
(5)
Multiple Device Markings will be inside parentheses. Only one Device Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a continuation
of the previous line and the two combined represent the entire Device Marking for that device.
(6)
Lead/Ball Finish - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead/Ball Finish values may wrap to two lines if the finish
value exceeds the maximum column width.
Addendum-Page 1
Samples
PACKAGE OPTION ADDENDUM
www.ti.com
27-May-2015
Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information
provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. TI has taken and
continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.
TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.
In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.
OTHER QUALIFIED VERSIONS OF LMX2492, LMX2492-Q1 :
• Catalog: LMX2492
• Automotive: LMX2492-Q1
NOTE: Qualified Version Definitions:
• Catalog - TI's standard catalog product
• Automotive - Q100 devices qualified for high-reliability automotive applications targeting zero defects
Addendum-Page 2
PACKAGE MATERIALS INFORMATION
www.ti.com
27-May-2015
TAPE AND REEL INFORMATION
*All dimensions are nominal
Device
Package Package Pins
Type Drawing
LMX2492QRTWRQ1
WQFN
RTW
24
LMX2492QRTWTQ1
WQFN
RTW
LMX2492RTWR
WQFN
RTW
LMX2492RTWT
WQFN
RTW
SPQ
Reel
Reel
A0
Diameter Width (mm)
(mm) W1 (mm)
B0
(mm)
K0
(mm)
P1
(mm)
W
Pin1
(mm) Quadrant
1000
178.0
12.4
4.3
4.3
1.3
8.0
12.0
Q1
24
250
178.0
12.4
4.3
4.3
1.3
8.0
12.0
Q1
24
1000
178.0
12.4
4.3
4.3
1.3
8.0
12.0
Q1
24
250
178.0
12.4
4.3
4.3
1.3
8.0
12.0
Q1
Pack Materials-Page 1
PACKAGE MATERIALS INFORMATION
www.ti.com
27-May-2015
*All dimensions are nominal
Device
Package Type
Package Drawing
Pins
SPQ
Length (mm)
Width (mm)
Height (mm)
LMX2492QRTWRQ1
WQFN
RTW
24
1000
213.0
191.0
55.0
LMX2492QRTWTQ1
WQFN
RTW
24
250
213.0
191.0
55.0
LMX2492RTWR
WQFN
RTW
24
1000
213.0
191.0
55.0
LMX2492RTWT
WQFN
RTW
24
250
213.0
191.0
55.0
Pack Materials-Page 2
MECHANICAL DATA
RTW0024A
SQA24A (Rev B)
www.ti.com
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