NSC LMV225TLX

LMV225/LMV226/LMV228
RF Power Detector for CDMA and WCDMA
General Description
Features
The LMV225/LMV226/LMV228 are 30 dB RF power detectors intended for use in CDMA and WCDMA applications.
The device has an RF frequency range from 450 MHz to 2
GHz. It provides an accurate temperature and supply compensated output voltage that relates linearly to the RF input
power in dBm. The circuit operates with a single supply from
2.7V to 5.5V. The LMV225/LMV226/LMV228 have an integrated filter for low-ripple average power detection of CDMA
signals with 30 dB dynamic range. Additional filtering can be
applied using a single external capacitor.
The LMV225 has an RF power detection range from –30
dBm to 0 dBm and is ideally suited for direct use in combination with resistive taps. The LMV226/LMV228 have a detection range from –15 dBm to 15 dBm and are intended for
use in combination with a directional coupler. The LMV226 is
equipped with a buffered output which makes it suitable for
GSM, EDGE, GPRS and TDMA applications.
n
n
n
n
n
n
30 dB linear in dB power detection range
Output voltage range 0.2 to 2V
Logic low shutdown
Multi-band operation from 450 MHz to 2000 MHz
Accurate temperature compensation
Packages:
— micro SMD package 1.0 mm x 1.0 mm x 0.6 mm
— LLP package 2.2 mm x 2.5 mm x 0.8 mm (LMV225
and LMV228)
Applications
n
n
n
n
CDMA RF power control
WCDMA RF power control
CDMA2000 RF power control
PA modules
The device is active for Enable = HI, otherwise it is in a low
power consumption shutdown mode. During shutdown the
output will be LOW. The output voltage ranges from 0.2V to
2V and can be scaled down to meet ADC input range requirements.
The LMV225/LMV226/LMV228 power detectors are offered
in the small 1.0 mm x 1.0 mm X 0.6 mm micro SMD package. The LMV225 and the LMV228 are also offered in the
2.2 mm x 2.5 mm x 0.8 mm LLP package.
Typical Application
LMV226/LMV228
LMV225
20076001
20076046
© 2005 National Semiconductor Corporation
DS200760
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LMV225/LMV226/LMV228 RF Power Detector for CDMA and WCDMA
March 2005
LMV225/LMV226/LMV228
Absolute Maximum Ratings (Note 1)
Junction Temperature (Note 3)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Mounting Temperature
Infrared or convection (20 sec)
Supply Voltage
VDD - GND
Supply Voltage
ESD Tolerance (Note 2)
2.7V to 5.5V
Temperature Range
2000V
Machine Model
−40˚C to +85˚C
RF Frequency Range
200V
Storage Temperature Range
235˚C
Operating Ratings (Note 1)
6.0V Max
Human Body Model
150˚C Max
450 MHz to 2 GHz
−65˚C to 150˚C
2.7 DC and AC Electrical Characteristics
Unless otherwise specified, all limits are guaranteed to VDD = 2.7V; TJ = 25˚C. Boldface limits apply at temperature extremes.
(Note 4)
Symbol
IDD
Parameter
Supply Current
Condition
Active Mode: RFIN/EN =
VDD (DC), No RF Input
Power Present
Min
Typ
Max
LMV225
4.8
7
8
LMV226
4.9
6.2
8
LMV228
4.9
6.2
8
0.44
4.5
µA
0.8
V
Shutdown: RFIN/EN = GND (DC), No
RF Input Power Present
VLOW
EN Logic Low Input Level
(Note 6)
VHIGH
EN Logic High Input Level
(Note 6)
ton
Turn-on-Time (Note 9)
tr
Rise Time (Note 7)
IEN
Current into RFIN/EN Pin
PIN
Input Power Range (Note 5)
1.8
No RF Input Power
Present, Output Loaded
with 10 pF
2.1
LMV226
1.2
LMV228
1.7
Step from no Power to 0
dBm Applied, Output
Loaded with 10 pF
LMV225
4.5
Step from no Power to 15
dBm Applied, Output
Loaded with 10 pF
LMV226
1.8
LMV228
4.8
LMV228
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µs
µs
1
LMV226
2
mA
V
LMV225
LMV225
Units
µA
−30
0
dBm
−43
−13
dBV
−15
15
dBm
−28
2
dBV
−15
15
dBm
−28
2
dBV
(Continued)
Unless otherwise specified, all limits are guaranteed to VDD = 2.7V; TJ = 25˚C. Boldface limits apply at temperature extremes.
(Note 4)
Symbol
Parameter
Logarithmic Slope (Note 8)
Condition
900 MHz
1800 MHz
1900 MHz
2000 MHz
Logarithmic Intercept (Note 8)
900 MHz
1800 MHz
1900 MHz
2000 MHz
VOUT
Output Voltage
No RF Input Power
Present
Min
Typ
LMV225
44.0
LMV226
44.5
LMV228
44.0
LMV225
39.4
LMV226
41.6
LMV228
41.9
LMV225
38.5
LMV226
41.2
LMV228
41.6
LMV225
38.5
LMV226
41.0
LMV228
41.2
LMV225
−45.5
LMV226
−24.5
LMV228
−27.2
−46.6
LMV226
−25.1
LMV228
−28.2
LMV225
−46.3
LMV226
−24.9
LMV228
−28.0
LMV225
−46.7
LMV226
−24.7
LMV228
−28.0
LMV225
214
350
LMV226
223
350
LMV228
228
350
Output Current
Sourcing/Sinking
LMV226 Only
ROUT
Output Impedance
LMV225/LMV228 only, no RF Input
Power Present
19.8
en
Output Referred Noise
RF Input = 1800 MHz, −10 dBm for
LMV225 and 5 dBm for
LMV226/LMV228, Measured at
10 kHz
700
4.5
Units
mV/dB
LMV225
IOUT
3
Max
dBm
5.3
mV
mA
29
34
kΩ
nV/
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LMV225/LMV226/LMV228
2.7 DC and AC Electrical Characteristics
LMV225/LMV226/LMV228
2.7 DC and AC Electrical Characteristics
(Continued)
Unless otherwise specified, all limits are guaranteed to VDD = 2.7V; TJ = 25˚C. Boldface limits apply at temperature extremes.
(Note 4)
Symbol
Parameter
Variation Due to Temperature
Condition
Min
Typ
900 MHz, RFIN = 0 dBm
Referred to 25˚C
LMV225
+0.64
−1.07
900 MHz, RFIN = 15 dBm
Referred to 25˚C
LMV226
+0.05
−0.02
LMV228
+0.22
−0.36
1800 MHz, RFIN = 0 dBm
Referred to 25˚C
LMV225
+0.09
−0.86
1800 MHz, RFIN = 15 dBm
Referred to 25˚C
LMV226
+0.07
−0.10
LMV228
+0.29
−0.57
1900 MHz, RFIN = 0 dBm
Referred to 25˚C
LMV225
+0
−0.69
1900 MHz, RFIN = 15 dBm
Referred to 25˚C
LMV226
+0
−0.10
LMV228
+0.23
−0.64
2000 MHz, RFIN = 0 dBm
Referred to 25˚C
LMV225
+0
−0.86
2000 MHz, RFIN = 15 dBm
Referred to 25˚C
LMV226
+0
−0.29
LMV228
+0.27
−0.65
Max
Units
dB
5.0 DC and AC Electrical Characteristics
Unless otherwise specified, all limits are guaranteed to VDD = 5.0V; TJ = 25˚C. Boldface limits apply at temperature extremes.
(Note 4)
Symbol
IDD
Parameter
Supply Current
Condition
Active Mode: RFIN/EN =
VDD (DC), no RF Input
Power Present.
Typ
Max
LMV225
Min
5.3
7.5
9
LMV226
5.3
6.8
9
LMV228
5.4
6.8
9
0.32
4.5
µA
0.8
V
Shutdown: RFIN/EN = GND (DC), no
RF Input Power Present.
VLOW
EN Logic Low Input Level
(Note 6)
VHIGH
EN Logic High Input Level
(Note 6)
ton
Turn-on-Time (Note 9)
tr
Rise Time (Note 7)
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1.8
No RF Input Power
Present, Output Loaded
with 10 pF
mA
V
LMV225
2.1
LMV226
1.0
LMV228
1.7
Step from no Power to 0
dBm Applied, Output
Loaded with 10 pF
LMV225
4.5
Step from no Power to 15
dBm Applied, Output
Loaded with 10 pF
LMV226
1.4
LMV228
4.8
4
Units
µs
µs
(Continued)
Unless otherwise specified, all limits are guaranteed to VDD = 5.0V; TJ = 25˚C. Boldface limits apply at temperature extremes.
(Note 4)
Symbol
Parameter
IEN
Current Into RFIN/EN Pin
PIN
Input Power Range (Note 5)
Condition
Min
LMV225
LMV226
LMV228
Logarithmic Slope (Note 8)
900 MHz
1800 MHz
1900 MHz
2000 MHz
Logarithmic Intercept (Note 8)
900 MHz
1800 MHz
1900 MHz
2000 MHz
VOUT
Output Voltage
No RF Input Power
Present
Typ
Units
1
µA
−30
0
dBm
−43
−13
dBV
−15
15
dBm
−28
2
dBV
−15
15
dBm
−28
2
dBV
LMV225
44.6
LMV226
44.6
LMV228
44.2
LMV225
40.6
LMV226
42.2
LMV228
42.4
LMV225
39.6
LMV226
41.8
LMV228
42.2
LMV225
39.7
LMV226
41.6
LMV228
41.8
LMV225
−47.0
LMV226
−25.0
mV/dB
LMV228
−27.7
LMV225
−48.5
LMV226
−25.7
LMV228
−28.9
LMV225
−48.2
LMV226
−25.6
LMV228
−28.7
LMV225
−48.9
LMV226
−25.5
LMV228
−28.7
LMV225
222
400
LMV226
231
400
LMV228
244
400
IOUT
Output Current
Sourcing/Sinking
LMV226 Only
ROUT
Output Impedance
No RF Input Power Present
23.7
en
Output Referred Noise
RF Input = 1800 MHz, −10 dBm for
LMV225 and 5 dBm for
LMV226/LMV228, Measured at
10 kHz
700
4.5
5
Max
dBm
5.3
mV
mA
29
31
kΩ
nV/
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LMV225/LMV226/LMV228
5.0 DC and AC Electrical Characteristics
LMV225/LMV226/LMV228
5.0 DC and AC Electrical Characteristics
(Continued)
Unless otherwise specified, all limits are guaranteed to VDD = 5.0V; TJ = 25˚C. Boldface limits apply at temperature extremes.
(Note 4)
Symbol
Parameter
Variation Due to Temperature
Condition
Min
Typ
900 MHz, RFIN = 0 dBm
Referred to 25˚C
LMV225
+0.89
−1.16
900 MHz, RFIN = 15 dBm
Referred to 25˚C
LMV226
+0.25
−0.16
LMV228
+0.46
−0.62
1800 MHz, RFIN = 0 dBm
Referred to 25˚C
LMV225
+0.3
−0.82
1800 MHz, RFIN = 15 dBm
Referred to 25˚C
LMV226
+0.21
−0.09
LMV228
+0.55
−0.78
1900 MHz, RFIN = 0 dBm
Referred to 25˚C
LMV225
+0.34
−0.63
1900 MHz, RFIN = 15 dBm
Referred to 25˚C
LMV226
+0.21
−0.19
LMV228
+0.55
−0.93
2000 MHz RFIN = 0 dBm
Referred to 25˚C
LMV225
+0.22
−0.75
2000 MHz RFIN = 15 dBm
Referred to 25˚C
LMV226
+0.25
−0.34
LMV228
+0.61
−0.91
Max
Units
dB
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is
intended to be functional, but specific performance is not guaranteed. For guaranteed specifications and the test conditions, see the Electrical Characteristics.
Note 2: Human body model: 1.5 kΩ in series with 100 pF. Machine model, 0Ω in series with 100 pF.
Note 3: The maximum power dissipation is a function of TJ(MAX) , θJA and TA. The maximum allowable power dissipation at any ambient temperature is PD =
(TJ(MAX) - TA)/θJA. All numbers apply for packages soldered directly into a PC board
Note 4: Electrical Table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating of
the device such that TJ = TA. No guarantee of parametric performance is indicated in the electrical tables under conditions of internal self-heating where TJ > TA.
Note 5: Power in dBV = dBm + 13 when the impedance is 50Ω.
Note 6: All limits are guaranteed by design or statistical analysis
Note 7: Typical values represent the most likely parametric norm.
Note 8: Device is set in active mode with a 10 kΩ resistor from VDD to RFIN/EN. RF signal is applied using a 50Ω RF signal generator AC coupled to the RFIN/EN
pin using a 100 pF coupling capacitor.
Note 9: Turn-on time is measured by connecting a 10 kΩ resistor to the RFIN/EN pin. Be aware that in the actual application on the front page, the RC-time constant
of resistor R2 and capacitor C adds an additional delay.
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6
LMV225/LMV226/LMV228
Connection Diagrams
4-Bump micro SMD
6-pin LLP
20076063
Top View
20076002
Top View
Pin Description
Pin
Name
micro SMD
LLP6
A2
4
B1
A1
B2
Power Supply
Output
Description
VDD
Positive Supply Voltage
1
GND
Power Ground
3
RFIN/EN
6
Out
DC voltage determines enable state of the device (HIGH = device
active). AC voltage is the RF input signal to the detector (beyond 450
MHz). The RFIN/EN pin is internally terminated with 50Ω in series with
45 pF.
Ground referenced detector output voltage (linear in dBm)
Ordering Information
Package
4-Bump micro SMD
6-pin LLP
Part Number
LMV225TL
LMV225TLX
LMV225SD
LMV225SDX
LMV226TL
4-Bump micro SMD
LMV226TLX
LMV228TL
LMV228TLX
6-pin LLP
LMV228SD
LMV228SDX
Package
Marking
I
A90
I
I
A89
Transport Media
250 Units Tape and Reel
3k Units Tape and Reel
2k Units Tape and Reel
9k Units Tape and Reel
NSC Drawing
Status
TLA04AAA
Released
SDB06A
Preliminary
TLA04AAA
Released
SDB06A
Preliminary
250 Units Tape and Reel
3k Units Tape and Reel
250 Units Tape and Reel
3k Units Tape and Reel
2k Units Tape and Reel
9k Units Tape and Reel
Note: This product is offered both with leaded and lead free bumps.
7
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LMV225/LMV226/LMV228
Block Diagrams
20076064
LMV225
20076049
LMV226
20076047
LMV228
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Unless otherwise specified, VDD = 2.7V, TJ = 25˚C.
Supply Current vs. Supply Voltage (LMV225)
Supply Current vs. Supply Voltage (LMV226)
20076004
20076051
Supply Current vs. Supply Voltage (LMV228)
Output Voltage vs. RF Input Power (LMV225)
20076034
20076005
Output Voltage vs. RF Input Power (LMV226)
Output Voltage vs. RF Input Power (LMV228)
20076052
20076035
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LMV225/LMV226/LMV228
Typical Performance Characteristics
LMV225/LMV226/LMV228
Typical Performance Characteristics Unless otherwise specified, VDD = 2.7V, TJ =
25˚C. (Continued)
Output Voltage and Log Conformance vs.
RF Input Power @ 900 MHz (LMV225)
Output Voltage and Log Conformance vs.
RF Input Power @ 900 MHz (LMV226)
20076053
20076006
Output Voltage and Log Conformance vs.
RF Input Power @ 1800 MHz (LMV225)
Output Voltage and Log Conformance vs.
RF Input Power @ 900 MHz (LMV228)
20076036
20076007
Output Voltage and Log Conformance vs.
RF Input Power @ 1800 MHz (LMV228)
Output Voltage and Log Conformance vs.
RF Input Power @ 1800 MHz (LMV226)
20076054
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20076037
10
Output Voltage and Log Conformance vs.
RF Input Power @ 1900 MHz (LMV225)
Output Voltage and Log Conformance vs.
RF Input Power @ 1900 MHz (LMV226)
20076055
20076008
Output Voltage and Log Conformance vs.
RF Input Power @ 2000 MHz (LMV225)
Output Voltage and Log Conformance vs.
RF Input Power @ 1900 MHz (LMV228)
20076038
20076009
Output Voltage and Log Conformance vs.
RF Input Power @ 2000 MHz (LMV228)
Output Voltage and Log Conformance vs.
RF Input Power @ 2000 MHz (LMV226)
20076056
20076039
11
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LMV225/LMV226/LMV228
Typical Performance Characteristics Unless otherwise specified, VDD = 2.7V, TJ =
25˚C. (Continued)
LMV225/LMV226/LMV228
Typical Performance Characteristics Unless otherwise specified, VDD = 2.7V, TJ =
25˚C. (Continued)
Logarithmic Slope vs. Frequency (LMV225)
Logarithmic Slope vs. Frequency (LMV226)
20076057
20076010
Logarithmic Slope vs. Frequency (LMV228)
Logarithmic Intercept vs. Frequency (LMV225)
20076040
20076011
Logarithmic Intercept vs. Frequency (LMV226)
Logarithmic Intercept vs. Frequency (LMV228)
20076058
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20076041
12
Output Variation vs. RF Input Power Normalized to 25˚C
@ 900 MHz (LMV225)
Output Variation vs. RF Input Power Normalized to 25˚C
@ 900 MHz (LMV226)
20076012
20076059
Output Variation vs. RF Input Power Normalized to 25˚C
@ 1800 MHz (LMV225)
Output Variation vs. RF Input Power Normalized to 25˚C
@ 900 MHz (LMV228)
20076042
20076013
Output Variation vs. RF Input Power Normalized to 25˚C
@ 1800 MHz (LMV228)
Output Variation vs. RF Input Power Normalized to 25˚C
@ 1800 MHz (LMV226)
20076060
20076043
13
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LMV225/LMV226/LMV228
Typical Performance Characteristics Unless otherwise specified, VDD = 2.7V, TJ =
25˚C. (Continued)
LMV225/LMV226/LMV228
Typical Performance Characteristics Unless otherwise specified, VDD = 2.7V, TJ =
25˚C. (Continued)
Output Variation vs. RF Input Power Normalized to 25˚C
@ 1900 MHz (LMV225)
Output Variation vs. RF Input Power Normalized to 25˚C
@ 1900 MHz (LMV226)
20076014
20076061
Output Variation vs. RF Input Power Normalized to 25˚C
@ 2000 MHz (LMV225)
Output Variation vs. RF Input Power Normalized to 25˚C
@ 1900 MHz (LMV228)
20076044
20076015
Output Variation vs. RF Input Power Normalized to 25˚C
@ 2000 MHz (LMV228)
Output Variation vs. RF Input Power Normalized to 25˚C
@ 2000 MHz (LMV226)
20076062
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20076045
14
LMV225/LMV226/LMV228
Typical Performance Characteristics Unless otherwise specified, VDD = 2.7V, TJ =
25˚C. (Continued)
PSRR vs. Frequency
(LMV225 , LMV226 and LMV228 in microSMD)
PSRR vs. Frequency
(LMV225 and LMV228 in LLP)
20076023
20076065
RF Input Impedance vs. Frequency @ Resistance and
Reactance (LMV225, LMV226 and LMV228 in micro SMD)
RF Input Impedance vs. Frequency @ Resistance and
Reactance (LMV225 and LMV228 in LLP)
20076024
20076066
15
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LMV225/LMV226/LMV228
Solving this expression for R1, using that RIN = 50Ω, yields:
Application Notes
CONFIGURING A TYPICAL APPLICATION
The LMV225/LMV226/LMV228 are power detectors intended for CDMA and WCDMA applications. Power applied
at its input translates to a DC voltage on the output through
a linear-in-dB response. The LMV225 detector is especially
suited for power measurements via a high-resistive tap,
while the LMV226/LMV228 are designed to be used in combination with a directional coupler. The LMV226 has an
additional output voltage buffer and therefore a low output
impedance. The key features of the devices are shown in
table 1.
(2)
In Figure 1, R1 is set to 1800Ω resulting in an attenuation of
31.4 dB
DIRECTIONAL COUPLER APPLICATION
The LMV226/LMV228 also has a 50Ω input resistance. However, its input range differs compared to the LMV225, i.e.
−15 dBm to +15 dBm. If a typical attenuation of a directional
coupler is 20 dB, the LMV226/LMV228 can be directly connected via the directional coupler to the PA without the need
of additional external attenuator (Figure 2). Different PA
ranges can be configured using couplers with other coupling
factors.
TABLE 1. DEVICE CHARACTERISTICS
Input Range
(dBm)
Output
Buffer
Application
LMV225
−30 / 0
No
High Resistive Tap
LMV226
−15 / 15
Yes
Directional Coupler
LMV228
−15 / 15
No
Directional Coupler
In order to match the output power range of the power
amplifier (PA) with the range of the LMV225’s input, the high
resistive tap needs to be configured correctly. In case of the
LMV226/LMV228 the coupling factor of the directional coupler needs to be chosen correctly.
HIGH RESISTIVE TAP APPLICATION
The constant input impedance of the device enables the
realization of a frequency independent input attenuation to
adjust the LMV225’s range to the range of the PA. Resistor
R1 and the 50Ω input resistance (RIN) of the device realize
this attenuation (Figure 1). To minimize insertion loss, resistor R1 needs to be sufficiently large. The following example
demonstrates how to determine the proper value for R1.
20076046
FIGURE 2. Typical LMV226/LMV228 Application with
Directional Coupler
SHUTDOWN FUNCTIONALITY
The LMV225/LMV226/LMV228 RFIN/EN pins have 2 functions combined:
• Enable/Shutdown
• Power input
The capacitor C and the resistor R2 (Figure 1 and Figure 2)
separate the DC shutdown functionality from the AC power
measurement. The device is active when Enable = HI, otherwise it is in a low power consumption shutdown mode.
During shutdown the output will be LOW.
Capacitor C should be chosen sufficiently large to ensure a
corner frequency far below the lowest input frequency to be
measured. In case of the LMV225 the corner frequency can
be calculated using:
20076033
FIGURE 1. Typical LMV225 Application with High
Resistive Tap
Suppose the useful output power of the PA ranges up to +31
dBm. As the LMV225 can handle input power levels up to 0
dBm. R1 should realize a minimum attenuation of 31 - 0 = 31
dB. The attenuation realized by R1 and the effective input
resistance RIN of the detector equals:
(3)
Where RIN = 50Ω, CIN = 45 pF typical.
With R1 = 1800Ω and C = 100 pF, this results in a corner
frequency of 2.8 MHz. This corner frequency is an indicative
(1)
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LMV225/LMV226/LMV228
Application Notes
(Continued)
number. The goal is to have a magnitude transfer, which is
sufficiently flat in the used frequency range; capacitor C
should be chosen significantly larger than capacitor CIN to
assure a proper performance of the high resistive tap. Capacitor C shouldn’t be chosen excessively large since the
RC-time, it introduces in combination with resistor R2, adds
to the turn-on time of the device.
The LMV226/LMV228 do not use a resistor R1 like the
LMV225. Though a resistor is seen on the coupler side
(RCOUPLER). Therefore a similar equation holds for the
LMV226/LMV228 LF corner frequency, where R1 is replaced
with the coupler output impedance (RCOUPLER).
With RCOUPLER = 50Ω and C = 100 pF, the resulting corner
frequency is 50 MHz.
The output voltage is proportional to the logarithm of the
input power, often called “linear-in-dB”. Figure 3 shows the
typical output voltage versus PA output power of the LMV225
setup as depicted in Figure 1.
20076017
FIGURE 4. AM Modulated RF Signal
The ripple observed at the output of the detector equals the
detectors response to the power variation at the input due to
AM modulation (Figure 4). This signal has a maximum amplitude VIN • (1+µ) and a minimum amplitude VIN • (1-µ),
where 1+µ can be maximum 2 and 1-µ can be minimum 0.
The amplitude of the ripple can be described with the formula:
(5)
where VY is the slope of the detection curve (Figure 5) and µ
is the modulation index. Equation (5) can be reduced to:
(6)
Consequently, the ripple is independent of the average input
power of the RF input signal and only depends on the
logarithmic slope VY and the ratio of the maximum and the
minimum input signal amplitude.
For CDMA, the ratio of the maximum and the minimum input
signal amplitude modulation is typically in the order of 5 to 6
dB, which is equivalent to a modulation index µ of 0.28 to
0.33.
A further understanding of the equation above can be
achieved via the knowledge that the output voltage VOUT of
the LMV225/LMV228 is linear in dB, or proportional to the
input power PIN in dBm. As discussed earlier, CDMA has a
modulation in the order of 5 to 6 dB. Since the transfer is
linear in dB, the output voltage VOUT will vary linearly over
about 5 to 6 dB in the curve (Figure 5).
20076016
FIGURE 3. Typical power detector response, VOUT vs.
PA output Power
OUTPUT RIPPLE DUE TO AM MODULATION
A CDMA modulated carrier wave generally contains some
amplitude modulation that might disturb the RF power measurement used for controlling the PA. This section explains
the relation between amplitude modulation in the RF signal
and the ripple on the output of the LMV225/LMV228. Expressions are provided to estimate this ripple on the output. The
ripple can be further reduced by lowpass filtering at the
output. This is realized by connecting an capacitor from the
output of the LMV225/LMV228 to ground.
Estimating Output Ripple
The CDMA modulated RF input signal of Figure 3 can be
described as:
(4)
VIN(t) = VIN [1 + µ(t)] cos (2 · π · f · t)
In which VIN is the amplitude of the carrier frequency and the
amplitude modulation µ(t) can be between -1 and 1.
17
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LMV225/LMV226/LMV228
Application Notes
a 1.5 nF capacitor is then 20 • log (200/12) = 24.4 dB. This
is very close to the calculated number of the previous paragraph.
(Continued)
20076025
20076018
FIGURE 6. Output Ripple vs. RF Input Power
FIGURE 5. VOUT vs. RF Input Power PIN
The output voltage variation ∆VOUT is thus identical for RF
input signals that fall within the linear range (in dB) of the
detector. In other words, the output variation is independent
of the absolute RF input signal:
(7)
∆VO = VY · ∆PIN
In which VYis the slope of the curve. The log-conformance
error is usually much smaller than the ripple due to AM
modulation. In case of the LMV225/LMV228, VY = 40 mV/
dB. With ∆PIN = 5 dB for CDMA, ∆VOUT = 200 mVPP. This is
valid for all VOUT.
PRINCIPLE OF OPERATION
The logarithmic response of the LMV225/LMV226/LMV228
is implemented by a logarithmic amplifier as shown in Figure
7. The logarithmic amplifier consists of a number of cascaded linear gain cells. With these gain cells, a piecewise
approximation of the logarithmic function is constructed.
Output Ripple with Additional Filtering
The calculated result above is for an unfiltered configuration.
When a low pass filter is used by shunting a capacitor of e.g.
COUT = 1.5 nF at the output of the LMV225/LMV228 to
ground, this ripple is further attenuated. The cut-off frequency follows from:
20076019
(8)
With the output resistance of the LMV225/LMV228 RO =
19.8 kΩ typical and COUT = 1.5 nF, the cut-off frequency
equals fC = 5.36 kHz. A 100 kHz AM signal then gets attenuated by 5.36/100 or 25.4 dB. The remaining ripple will be
less than 20 mV. With a slope of 40 mV/dB this translates
into an error of less than ± 0.5 dB. Since the LMV226 has a
low output impedance buffer, a capacitor to reduce the ripple
will not be effective.
FIGURE 7. Logarithmic Amplifier
Every gain cell has a response according to Figure 8. At a
certain threshold (EK), the gain cell starts to saturate, which
means that the gain drops to zero. The output of gain cell 1
is connected to the input of gain cell 2 and so on.
Output Ripple Measurement
Figure 6 shows the ripple reduction that can be achieved by
adding additional capacitance at the output of the LMV225/
LMV228. The RF signal of 900 MHz is AM modulated with a
100 kHz sinewave and a modulation index of 0.3. The RF
input power is swept while the modulation index remains
unchanged. Without the output capacitor the ripple is about
200 mVPP. Connecting a capacitor of 1.5 nF at the output to
ground, results in a ripple of 12 mVPP. The attenuation with
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18
Figure 10 shows a logarithmic function on a logarithmic
scale and the piecewise approximation of the logarithmic
function.
(Continued)
20076020
FIGURE 8. Gain Cell
All gain cell outputs are AM-demodulated with a peak detector and summed together. This results in a logarithmic function. The logarithmic range is about:
20076022
20 · n · log (A)
FIGURE 10. Log-Function on Log Scale
where,
The maximum error for this approximation occurs at the
geometric mean of a gain section, which is e.g. for the third
segment:
n = number of gain cells
A = gain per gaincell
Figure 9 shows a logarithmic function on a linear scale and
the piecewise approximation of the logarithmic function.
(9)
The size of the error increases with distance between the
thresholds.
LAYOUT CONSIDERATIONS
For a proper functioning part a good board layout is necessary. Special care should be taken for the series resistance
R1 (Figure 1) that determines the attenuation. For high resistor values the parasitic capacitance of the resistor may
significantly impact the realized attenuation. The effective
attenuation will be lower than intended. To reduce the parasitic capacitance across resistor R1, this resistor can be
composed of several components in series instead of using
a single component.
20076021
FIGURE 9. Log-Function on Lin Scale
19
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LMV225/LMV226/LMV228
Application Notes
LMV225/LMV226/LMV228
Physical Dimensions
inches (millimeters) unless otherwise noted
NOTES: UNLESS OTHERWISE SPECIFIED
1. EPOXY COATING
2. FOR SOLDER BUMP COMPOSITION, SEE “SOLDER INFORMATION” IN THE PACKAGE SECTION OF THE NATIONAL SEMICONDUCTOR WEB PAGE
(www.national.com).
3. RECOMMEND NON-SOLDER MASK DEFINED LANDING PAD.
4. PIN A1 IS ESTABLISHED BY LOWER LEFT CORNER WITH RESPECT TO TEXT ORIENTATION. REMAINING PINS ARE NUMBERED COUNTER
CLOCKWISE.
5. XXX IN DRAWING NUMBER REPRESENTS PACKAGE SIZE VARIATION WHERE X1 IS PACKAGE WIDTH, X2 IS PACKAGE LENGTH AND X3 IS
PACKAGE HEIGHT.
REFERENCE JEDEC REGISTRATION MO-211, VARIATION BC.
4-Bump micro SMD
NS Package Number TLA04AAA
X1 = 1.014 ± 0.030 mm X2 = 1.014 ± 0.030 mm X3 = 0.600 ± 0.075 mm
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20
inches (millimeters) unless otherwise noted (Continued)
6-Pin LLP
NS Package Number SDB06A
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LMV225/LMV226/LMV228 RF Power Detector for CDMA and WCDMA
Physical Dimensions