LINER LTC5582 40mhz to 10ghz rms power detector with 57db dynamic range Datasheet

LTC5582
40MHz to 10GHz
RMS Power Detector with
57dB Dynamic Range
Features
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Description
Frequency Range: 40MHz to 10GHz
Linear Dynamic Range: Up to 57dB
Accurate RMS Power Measurement of High Crest
Factor Modulated Waveforms
Exceptional Accuracy Over Temperature: ±0.5dB (Typ)
Low Linearity Error within Dynamic Range
Single-Ended or Differential RF Inputs
Fast Response Time: 90ns Rise Time
Low Supply Current: 41.6mA at 3.3V (Typ)
Small 3mm × 3mm DFN10
Applications
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RMS Power Measurement
PA Power Control
Receive and Transmit Gain Control
LTE, WiMAX, W-CDMA, CDMA2K, TD-SCDMA,
EDGE Basestations
Point-to-Point Microwave Links
RF Instrumentation
The LTC®5582 is a 40MHz to 10GHz RMS responding power
detector. It is capable of accurate power measurement
of an AC signal with wide dynamic range, from –60dBm
to 2dBm depending on frequency. The power of the AC
signal in an equivalent decibel-scaled value is precisely
converted into DC voltage on a linear scale, independent of
the crest factor of the input signal waveforms. The LTC5582
is suitable for precision RF power measurement and level
control for a wide variety of RF standards, including LTE,
WiMAX, W-CDMA, CDMA2000, TD-SCDMA, and EDGE.
The DC output is buffered with a low output impedance
amplifier capable of driving a high capacitance load. Consult factory for more information. The part is packaged in
a 10-lead 3mm × 3mm DFN. It is pin-to-pin compatible
with the LT5570.
L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks of Linear
Technology Corporation. All other trademarks are the property of their respective owners.
Protected by U.S. Patents including 7262661, 7317357, 7622981.
Typical Application
Linearity Error vs RF Input Power
2140MHz Modulated Waveforms
40MHz to 6GHz RMS Power Detector
3
TA = 25°C
3.3V
FLTR
VCC
IN+
270pF
68Ω
1nF
2
100nF
1nF
LTC5582
EN
DEC
RT1
IN–
RT2
GND
OUT
5582 TA01a
ENABLE
VOUT
LINEARITY ERROR (dB)
1µF
1
0
–1
–2
–3
–65
4-CARRIER WCDMA
CW
3-CARRIER CDMA2K
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 TAO1b
5582f
LTC5582
Absolute Maximum Ratings
Pin Configuration
(Note 1)
TOP VIEW
Supply Voltage..........................................................3.8V
Enable Voltage................................. –0.3V to VCC + 0.3V
Input Signal Power (Single-Ended, 50Ω)..............18dBm
Input Signal Power (Differential, 50Ω)..................24dBm
TJMAX..................................................................... 150°C
Operating Temperature Range..................–40°C to 85°C
Storage Temperature Range................... –65°C to 125°C
VCC
10 FLTR
1
IN+
2
DEC
3
IN–
4
GND
5
11
GND
9 EN
8 RT1
7 RT2
6 OUT
DD PACKAGE
10-LEAD (3mm s 3mm) PLASTIC DFN
TJMAX = 150°C, θJA = 43°C/W
EXPOSED PAD (PIN 11) IS GND, MUST BE SOLDERED TO PCB
Order Information
LEAD FREE FINISH
TAPE AND REEL
PART MARKING
PACKAGE DESCRIPTION
TEMPERATURE RANGE
LTC5582IDD#PBF
LTC5582IDD#TRPBF
LFGZ
10-Lead 3mm × 3mm Plastic DFN
–40°C to 85°C
Consult LTC Marketing for parts specified with wider operating temperature ranges.
Consult LTC Marketing for information on non-standard lead based finish parts.
For more information on lead free part marking, go to: http://www.linear.com/leadfree/
For more information on tape and reel specifications, go to: http://www.linear.com/tapeandreel/
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VCC = 3.3V, EN = 3.3V. Test circuit is shown in Figure 1. (Notes 2 and 3).
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
AC Input
Input Frequency Range (Note 4)
40 to 10000
MHz
Differential
400//0.5
Ω//pF
RF Input Power Range
CW; Single-Ended, 50Ω
–57 to 2
dBm
Linear Dynamic Range
±1dB Linearity Error
Input Impedance
fRF = 450MHz
59
Output Slope
Logarithmic Intercept
Output Variation vs Temperature
Normalized to Output at 25°C, Pin = –50dBm to 0dBm
Deviation from CW Response
11dB Peak to Average Ratio (3-Carrier CDMA2K)
12dB Peak to Average Ratio (4-Carrier WCDMA)
l
dB
29.5
mV/dB
–86.2
dBm
±0.5
dB
0.1
0.1
dB
dB
2nd Order Harmonic Distortion
At RF Input; CW Input; PIN = 0dBm
67
dBc
3rd Order Harmonic Distortion
At RF Input; CW Input; PIN = 0dBm
62
dBc
5582f
LTC5582
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VCC = 3.3V, EN = 3.3V. Test circuit is shown in Figure 1. (Notes 2 and 3).
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
fRF = 880MHz
RF Input Power Range
CW; Single-Ended, 50Ω
Linear Dynamic Range
±1dB Linearity Error
–57 to 2
dBm
59
Output Slope
Logarithmic Intercept
dB
29.3
mV/dB
–86.4
dBm
±0.5
dB
Output Variation vs Temperature
Normalized to Output at 25°C, Pin = –50dBm to 0dBm
Deviation from CW Response
11dB Peak to Average Ratio (3-Carrier CDMA2K)
12dB Peak to Average Ratio (4-Carrier WCDMA)
0.1
0.1
dB
dB
2nd Order Harmonic Distortion
At RF Input; CW Input; PIN = 0dBm
69
dBc
3rd Order Harmonic Distortion
At RF Input; CW Input; PIN = 0dBm
59
dBc
–56 to 1
dBm
l
fRF = 2140MHz
RF Input Power Range
CW; Single-Ended, 50Ω
Linear Dynamic Range (Note 5)
±1dB Linearity Error
Output Slope
Logarithmic Intercept
50
57
26
29.5
33
mV/dB
–85
–72
dBm
–98
Output Variation vs Temperature
Normalized to Output at 25°C, Pin = –47dBm to 0dBm
Deviation from CW Response
11 dB Peak to Average Ratio (3-Carrier CDMA2K)
12dB Peak to Average Ratio (4-Carrier WCDMA)
l
dB
±0.5
dB
0.1
0.1
dB
dB
fRF = 2700MHz
RF Input Power Range
CW; Single-Ended, 50Ω
Linear Dynamic Range
±1dB Linearity Error
–55 to 1
56
Output Slope
Logarithmic Intercept
Output Variation vs Temperature
Normalized to Output at 25°C, Pin = –47dBm to 0dBm
Deviation from CW Response
12dB Peak to Average Ratio (WiMAX OFDM)
l
dBm
dB
29.8
mV/dB
–83.8
dBm
±0.5
dB
0.2
dB
fRF = 3800MHz
RF Input Power Range
CW; Single-Ended, 50Ω
Linear Dynamic Range
±1dB Linearity Error
–51 to 2
53
Output Slope
Logarithmic Intercept
Output Variation vs Temperature
Normalized to Output at 25°C, Pin = –51dBm to 2dBm
Deviation from CW Response
12dB Peak to Average Ratio (WiMAX OFDM)
l
dBm
dB
30.3
mV/dB
–81
dBm
±1
dB
0.2
dB
fRF = 5800MHz
RF Input Power Range
CW; Single-Ended, 50Ω
Linear Dynamic Range
±1dB Linearity Error
–46 to 3
49
dBm
dB
Output Slope
30.9
mV/dB
Logarithmic Intercept
–74.7
dBm
Output Variation vs Temperature
Normalized to Output at 25°C, Pin = –46dBm to 2dBm
Deviation from CW Response
12dB Peak to Average Ratio (WiMAX OFDM)
l
±1
dB
0.2
dB
5582f
LTC5582
Electrical Characteristics
The l denotes the specifications which apply over the full operating
temperature range, otherwise specifications are at TA = 25°C. VCC = 3.3V, EN = 3.3V. Test circuit is shown in Figure 1. (Notes 2 and 3).
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
Output Interface
Output DC Voltage
No RF Signal Present
0.69
Output Impedance
V
100
Ω
Output Current
Maximum
±5
mA
Rise Time, 10% to 90%
0.8V to 2.4V, C3 = 8nF, fRF = 100MHz
90
nS
Fall Time, 90% to 10%
2.4V to 0.8V, C3 = 8nF, fRF = 100MHz
5
μS
Enable (EN) Low = Off, High = On
EN Input High Voltage (On)
l
EN Input Low Voltage (Off)
l
1
V
0.4
V
200
μA
Enable Pin Input Current
EN = 3.3V
125
Turn ON Time
VOUT within 10% of Final Value, C3 = 8nF
2.8
μs
Turn OFF Time
VOUT < 0.8V, C3 = 8nF
40
μs
Power Supply
Supply Voltage
Supply Current
Note 1: Stresses beyond those listed under Absolute Maximum Ratings
may cause permanent damage to the device. Exposure to any Absolute
Maximum Rating condition for extended periods may affect device
reliability and lifetime.
Note 2: The LTC5582 is guaranteed functional over the temperature range
–40°C to 85°C.
Note 3: Logarithmic Intercept is an extrapolated input power level from the
best fitted log-linear straight line, where the output voltage is 0V.
Typical Performance Characteristics
Output Voltage vs RF Input Power
52
mA
0.1
10
μA
Supply Current vs Supply Voltage
60
TA = 25°C
55
2.0
1.6
450MHz
880MHz
2140MHz
2700MHz
3800MHz
5800MHz
1.2
0.8
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
1
0
–1
–2
5
5582 G01
SUPPLY CURRENT (mA)
2
LINEARITY ERROR (dB)
2.4
OUTPUT VOLTAGE (V)
41.6
VCC = 3.3V, EN = 3.3V, TA = 25°C unless otherwise
Linearity Error vs RF Input Power
3
TA = 25°C
–55
V
Note 4: Operation over a wider frequency range is possible with reduced
performance. Consult the factory for information and assistance.
Note 5: The linearity error is calculated by the difference between the
incremental slope of the output and the average output slope from
–50dBm to –5dBm. The dynamic range is defined as the range over which
the linearity error is within ±1dB.
noted. Test circuits shown in Figure 1.
0.4
–65
3.5
EN = 0V, VCC = 3.5V
Shutdown Current
2.8
3.3
3.1
–3
–65
450MHz
880MHz
2140MHz
2700MHz
3800MHz
5800MHz
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
TA = 85°C
TA = 25°C
TA = –40°C
50
45
40
35
30
25
–5
5
5582 G02
20
3.0
3.1
3.3
3.2
3.4
SUPPLY VOLTAGE (V)
3.5
3.6
5582 G27
5582f
LTC5582
Typical Performance Characteristics
noted. Test circuits shown in Figure 1.
Output Voltage Temperature
Variation from 25°C, 450MHz
3
2
2
2.0
1
1.6
0
1.2
–1
0.8
0.4
–65
TA = 85°C
TA = 25°C
TA = –40°C
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
LINEARITY ERROR (dB)
OUTPUT VOLTAGE (V)
2.4
3
VOUT VARIATION (dB)
Rt1 = 12k
Rt2 = 2k
Linear Error vs RF Input Power,
Modulated Waveforms, 450MHz
3
Rt1 = 12k
Rt2 = 2k
1
TA = 85°C
0
TA = –40°C
–1
–2
–2
–3
–3
–65
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
2
1
1.6
0
1.2
–1
TA = 85°C
TA = 25°C
TA = –40°C
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
1
–1
–2
–3
–3
–65
3
2
2
0
1.2
–1
TA = 85°C
TA = 25°C
TA = –40°C
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 G09
VOUT VARIATION (dB)
3
1.6
–55
0
–1
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
–3
–65
5
4-CARRIER WCDMA
CW
3-CARRIER CDMA2K
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
0
3
–2
–3
–3
–65
TA = 85°C
TA = –40°C
1
0
–1
–2
–55
TA = 25°C
2
–1
–2
5
Linear Error vs RF Input Power,
Modulated Waveforms, 2140MHz
Rt1 = 0
Rt2 = 2k
1
–5
5582 G08
Output Voltage Temperature
Variation from 25°C, 2140MHz
1
0.4
–65
1
–2
–55
5
TA = 25°C
5582 G07
2.0
0.8
–5
2
TA = –40°C
–2
LINEARITY ERROR (dB)
OUTPUT VOLTAGE (V)
2.4
–45 –35 –25 –15
RF INPUT POWER (dBm)
3
TA = 85°C
0
Output Voltage, Linearity Error vs
RF Input Power, 2140MHz
Rt1 = 0
Rt2 = 2k
–55
Linear Error vs RF Input Power,
Modulated Waveforms, 880MHz
Rt1 = 12k
Rt2 = 2k
5582 G06
2.8
4-CARRIER WCDMA
CW
3-CARRIER CDMA2K
5582 G05
LINEARITY ERROR (dB)
–55
–3
–65
5
LINEARITY ERROR (dB)
2
VOUT VARIATION (dB)
3
LINEARITY ERROR (dB)
OUTPUT VOLTAGE (V)
3
2.0
0.4
–65
–1
Output Voltage Temperature
Variation from 25°C, 880MHz
Rt1 = 12k
Rt2 = 2k
0.8
0
5582 G04
Output Voltage, Linearity Error vs
RF Input Power, 880MHz
2.4
1
–2
5582 G03
2.8
TA = 25°C
2
LINEARITY ERROR (dB)
Output Voltage, Linearity Error vs
RF Input Power, 450MHz
2.8
VCC = 3.3V, EN = 3.3V, TA = 25°C unless otherwise
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 G10
–3
–65
4-CARRIER WCDMA
CW
3-CARRIER CDMA2K
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 G11
5582f
LTC5582
Typical Performance Characteristics
noted. Test circuits shown in Figure 1.
Output Voltage Temperature
Variation from 25°C, 2700MHz
3
2
2
2.0
1
1.6
0
1.2
–1
0.4
–65
TA = 85°C
TA = 25°C
TA = –40°C
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
3
Rt1 = 0
Rt2 = 1.6k
1
TA = –40°C
0
–1
–2
–2
–3
–3
–65
2
2
1
1.6
0
1.2
–1
0.4
–65
TA = 85°C
TA = 25°C
TA = –40°C
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
VOUT VARIATION (dB)
3
LINEARITY ERROR (dB)
OUTPUT VOLTAGE (V)
3
2.0
0.8
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
3
0
TA = 85°C
–1
–2
–3
–3
–65
2
1.6
0
1.2
–1
0.4
–65
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
1
5
5582 G18
CW
0
WiMAX
–1
–2
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
–3
–65
5
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
Linear Error vs RF Input Power,
Modulated Waveforms, 5800MHz
3
Rt1 = 0
Rt2 = 3k
TA = 85°C
TA = –40°C
–1
–2
–2
–3
–3
–65
TA = 25°C
2
1
0
5
5582 G17
LINEARITY ERROR (dB)
2
VOUT VARIATION (dB)
3
LINEARITY ERROR (dB)
OUTPUT VOLTAGE (V)
3
5
TA = 25°C
5582 G16
1
TA = 85°C
TA = 25°C
TA = –40°C
–5
2
TA = –40°C
–2
2.0
0.8
–45 –35 –25 –15
RF INPUT POWER (dBm)
Linear Error vs RF Input Power,
Modulated Waveforms, 3800MHz
Output Voltage Temperature
Variation from 25°C, 5800MHz
Rt1 = 0
Rt2 = 3k
–55
5582 G14
Rt1 = 0
Rt2 = 1.6k
1
Output Voltage, Linearity Error vs
RF Input Power, 5800MHz
2.4
–3
–65
5
5582 G15
2.8
WiMAX
–1
Output Voltage Temperature
Variation from 25°C, 3800MHz
Rt1 = 0
Rt2 = 1.6k
CW
0
5582 G13
Output Voltage, Linearity Error vs
RF Input Power, 3800MHz
2.4
1
–2
5582 G12
2.8
TA = 25°C
2
TA = 85°C
LINEARITY ERROR (dB)
0.8
LINEARITY ERROR (dB)
OUTPUT VOLTAGE (V)
2.4
3
VOUT VARIATION (dB)
Rt1 = 0
Rt2 = 1.6k
Linear Error vs RF Input Power,
Modulated Waveforms, 2700MHz
LINEARITY ERROR (dB)
Output Voltage, Linearity Error vs
RF Input Power, 2700MHz
2.8
VCC = 3.3V, EN = 3.3V, TA = 25°C unless otherwise
1
CW
0
WiMAX
–1
–2
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 G19
–3
–65
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 G20
5582f
LTC5582
Typical Performance Characteristics
VCC = 3.3V, EN = 3.3V, TA = 25°C unless otherwise
noted. Test circuits shown in Figure 1.
Output Voltage Temperature
Variation from 25°C, 8GHz
Output Voltage Linearity Error vs
RF Input Power, 10GHz
2.8
3
2.4
2
2
2.4
2
2.0
1
2.0
1
1.6
0
1.6
0
1.2
–1
1.2
–1
0.8
TA = 85°C
TA = 25°C
TA = –40°C
0.4
–45
–35
–25
–5
–15
RF INPUT POWER (dBm)
5 10
1
OUTPUT VOLTAGE (V)
3
VOUT VARIATION (dB)
3
TA = 85°C
0
TA = –40°C
–1
–2
–2
0.8
–3
–3
–45
–35
–25
–15
–5
RF INPUT POWER (dBm)
5 10
5582 G30
31.0
2
30.5
TA = 85°C
–1
–45
–35
–25
–15
–5
RF INPUT POWER (dBm)
5 10
29.5
29.0
28.0
–81
–84
–87
0
1
2
4
3
FREQUENCY (GHz)
5
–90
6
25
25
20
15
10
5
2
4
3
FREQUENCY (GHz)
1
5
4.8
TA = 85°C
TA = 25°C
TA = –40°C
20
4.0
10
5
fRF = 100MHz
RF PULSE ON
4.4
15
6
Output Transient Response,
C3 = 8nF
OUTPUT VOLTAGE (V)
TA = 85°C
TA = 25°C
TA = –40°C
0
5582 G22
Logarithmic Intercept Distribution
vs Temperature, 2140MHz
PERCENTAGE DISTRIBUTION (%)
PERCENTAGE DISTRIBUTION (%)
30
–78
5582 G21
Slope Distribution vs
Temperature, 2140MHz
–3
TA = 85°C
TA = 25°C
TA = –40°C
–75
30.0
5582 G33
35
–72
TA = 85°C
TA = 25°C
TA = –40°C
28.5
–2
5 10
Logarithmic Intercept vs
Frequency
INTERCEPT (dBm)
SLOPE (mV/dB)
VOUT VARIATION (dB)
3
0
–25
–15
–5
RF INPUT POWER (dBm)
5582 G32
Slope vs Frequency
TA = –40°C
–35
5582 G31
Output Voltage Temperature
Variation from 25°C, 10GHz
1
–2
TA = 85°C
TA = 25°C
TA = –40°C
0.4
–45
LINEARITY ERROR (dB)
2.8
LINEARITY ERROR (dB)
OUTPUT VOLTAGE (V)
Output Voltage, Linearity Error vs
RF Input Power, 8GHz
RF PULSE OFF
3.6
RF PULSE OFF
3.2
PIN = 0dBm
PIN = –10dBm
PIN = –20dBm
PIN = –30dBm
PIN = –40dBm
PIN = –50dBm
2.8
2.4
2.0
1.6
1.2
0.8
0
27.9
28.5
29.1
29.7
SLOPE (mV/dB)
30.3
5582 G23
0
–90
–88
–86
–84
–82
–80
LOGRITHMIC INTERCEPT (dBm)
5582 G24
0.4
0
1
2
3
4 5 6
TIME (µs)
7
8
9
10
5582 G25
5582f
LTC5582
Typical Performance Characteristics
noted. Test circuits shown in Figure 1.
Output Transient Response,
C3 = 1µF
OUTPUT VOLTAGE (V)
RF PULSE OFF
3.6
RF PULSE OFF
3.2
2.8
2.4
2.0
1.6
PIN = 0dBm
PIN = –10dBm
PIN = –20dBm
PIN = –30dBm
PIN = –40dBm
PIN = –50dBm
1.2
SUPPLY CURRENT (mA)
55
4.0
0
TA = 85°C
TA = 25°C
TA = –40°C
–5
50
45
40
35
30
–10
–15
–20
25
0.8
0.4
60
fRF = 100MHz
RF PULSE ON
4.4
RF Input Return Loss vs
Frequency
Supply Current vs RF Input Power
RETURN LOSS (dB)
4.8
VCC = 3.3V, EN = 3.3V, TA = 25°C unless otherwise
0
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0
TIME (ms)
5582 G26
20
–65
–55
–45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 G28
–25
0
1
3
2
4
FREQUENCY (GHz)
5
6
5582 G22
Pin Functions
VCC (Pin 1): Power Supply Pin. Typical current consumption is 41.6mA at room temperature. This pin should be
externally bypassed with 1nF and 1µF chip capacitors.
IN+, IN– (Pins 2, 4): Differential Input Signal Pins. Either
one can be driven with a single-ended signal while the
other is AC-coupled to ground. These pins can also be
driven with a differential signal. The pins are internally
biased to 1.585V and should be DC blocked externally. The
differential impedance is typically 400Ω. The impedance
of each pin to the DEC pin is 200Ω.
RT2 (Pin 7): Optional Control Pin for 2nd-Order Output
Temperature Compensation. Connect this pin to ground to
disable it. The output voltage will decrease with respect to
the room temperature (25°C) by connecting it to ground
via an off-chip resistor when the ambient temperature is
either higher or lower.
RT1 (Pin 8): Optional Control Pin for 1st-Order Output
Temperature Compensation. Connect this pin to ground
to disable it. The output voltage will increase inversely
proportional to ambient temperature.
DEC (Pin 3): Input Common Mode Decoupling Pin. This
pin is internally biased to 1.585V and connected to an onchip 50pF capacitor to ground. The impedance between
DEC and IN+ (or IN–) is 200Ω. The pin can be connected
to the center tap of an external balun when terminated
differentially. The pin can be floating or connected to
ground via an AC-decoupling capacitor when driven either
in single-ended or differential input configuration.
EN (Pin 9): Enable Pin. An applied voltage above 1V will
activate the bias for the IC. For an applied voltage below
0.4V, the circuits will be shut down (disabled) with a reduction in power supply current. If the enable function is not
required, then this pin can be connected to VCC. Typical
enable pin input current is 100μA for EN = 3.3V. Note that
at no time should the Enable pin voltage be allowed to
exceed VCC by more than 0.3V.
GND (Pin 5, Exposed Pad Pin 11): Circuit Ground Return
for the Entire IC. This must be soldered to the printed
circuit board ground plane.
FLTR (Pin 10): Connection for an External Filtering Capacitor C3. A minimum of 8nF capacitance is required for stable
AC average power measurement. This capacitor should
be connected to VCC.
OUT (Pin 6): DC Output Pin. The output impedance is mainly
determined by an internal 100Ω series resistance which
provides protection if the output is shorted to ground.
5582f
LTC5582
Test Circuits
R1
1.5Ω
1
C4
270pF
J1
RF INPUT
C5
0.4pF
2
R4
68Ω
C8
1nF
NC
3
4
C9
100pF
5
FLTR
VCC
IN+
LTC5582
EN
DEC
RT1
IN–
RT2
GND
OUT
EXPOSED PAD
11
REF DES
5582 F01
10
C3
100nF
C2
1nF
C1
1µF
9
3.3V
EN
R3
100k
8
7
6
OUT
C10
OPTIONAL
R5
2k
R6
0Ω
VALUE
SIZE
PART NUMBER
C1
1uF
0402
MURATA GRM155R60J105KE19
C2, C8
1nF
0402
MURATA GRM155R71H102KA01
C3
100nF
0402
TDK CID05X7R1C104K
C4
270pF
0402
MURATA GRM155CIH271JA01
C5
0.4pF
0402
MURATA GJM1555C1HR40BB01
C9
100pF
0402
AVX 0402YC101KAT
R1
1.5Ω
0603
VISHAY CRCW06031R50JNEA
R3
100KΩ
0402
VISHAY CRCW0402100KFKED
R4
68Ω
0402
VISHAY CRCW040268R1FKED
R5
2k
0402
VISHAY CRCW04022K00FKEA
R6
0
0402
VISHAY CRCW0402020000Z0ED
Figure 1. Test Schematic Optimized for 40MHz to 5500MHz in Single-Ended Input Configuration
Figure 2. Top Side of Evaluation Board
5582f
LTC5582
Applications Information
The LTC5582 is a true RMS RF power detector, capable
of measuring an RF signal over the frequency range from
40MHz to 10GHz, independent of input waveforms with
different crest factors such as CW, CDMA2K, WCDMA,
LTE and WiMAX signals. Up to 60dB dynamic range is
achieved with a very stable output within the full temperature range from –40°C to 85°C. Its sensitivity can be
as low as –57dBm up to 2.7GHz even with single-ended
50Ω input termination.
RF Inputs
The differential RF inputs are internally biased at 1.585V.
The differential impedance is 400Ω. These pins should be
DC blocked when connected to ground or other matching
components.
The LTC5582 can be driven in a single-ended configuration
as illustrated in Figure 3. The single-ended input impedance
vs frequency is detailed in Table 1. The DEC Pin can be
either left floating or AC-coupled to ground via an external
capacitor. While the RF signal is applied to the IN+ (or IN–)
Pin, the other pin IN– (or IN+) should be AC-coupled to
ground. By simply terminating a 68Ω resistor between the
IN+ and IN– Pins and coupling the non-signal side to ground
using a 1nF capacitor, broadband 50Ω input matching can
be achieved with typical return loss better than 10dB from
40MHz to 5.5GHz. At higher RF frequencies, additional
matching components may be needed.
J1
RF INPUT
LTC5582
C4
1nF
2
C5
3
R4
68Ω
C9
OPTIONAL
VCC
IN+
DEC
200Ω
50pF
C8
1nF
4
IN–
200Ω
5582 F03
Figure 3. Single-Ended Input Configuration
Table 1. Single-Ended Input Impedance (DEC Floating)
S11
FREQUENCY
(MHZ)
INPUT IMPEDANCE
(Ω)
MAG
ANGLE (˚)
40
220.7-j63.0
0.655
–7.0
100
195.2-j47.3
0.611
–7.1
200
175.1-j37.6
0.571
–7.3
400
200.9-j42.2
0.618
–6.3
600
159.8-j52.9
0.563
–11.5
800
154.8-j52.4
0.554
–12.2
1000
158.6-j57.1
0.568
–12.4
1200
164.1-j81.1
0.612
–14.7
1400
138.1-j110.5
0.650
–21.0
1600
102.7-j113.3
0.659
–28.5
1800
80.1-j103.1
0.647
–35.3
2000
67.1-j92.0
0.628
–41.3
2200
58.4-j82.3
0.607
–46.7
2400
52.9-j74.5
0.586
–52.0
2600
48.5-j67.6
0.566
–57.0
2800
44.8-j61.5
0.546
–62.0
3000
41.8-j56.1
0.526
–66.9
3200
41.8-j56.3
0.508
–72.0
3400
37.3-j47.0
0.490
–77.1
3600
35.4-j42.9
0.473
–80.2
3800
33.9-j39.1
0.457
–87.7
4000
32.4-j35.5
0.445
–93.1
4200
31.1-j32.3
0.429
–98.8
4400
29.9-j29.1
0.416
–104.7
4600
28.9-j26.2
0.405
–110.7
4800
27.9-j23.3
0.395
–117.0
5000
27.0-j20.5
0.388
–123.5
5200
26.2-j17.8
0.382
–130.2
5400
25.4-j15.2
0.376
–136.9
5600
24.7-j12.6
0.376
–144.1
5800
24.0-j10.0
0.377
–151.3
6000
23.3-j7.5
0.377
–158.4
The LTC5582 differential inputs can also be driven from
a fully balanced source as shown in Figure 4. When the
signal source is a single-ended 50Ω, conversion to a differential signal can be achieved using a 1:8 balun to match
the internal 400Ω input impedance to the 50Ω source.
This impedance transformation results in 9dB voltage
gain, thus 9dB improvement in sensitivity is obtained
5582f
10
LTC5582
Applications Information
while the overall dynamic range remains the same. At
high frequency, additional LC elements may be needed
for the input impedance matching due to the parasitics
of the transformer and PCB traces.
LTC5582
J1
RF INPUT
2
3
MATCHING NETWORK
CS1
6.8pF
VCC
TO IN–
IN+
DEC
5582 F05
Figure 5. Single-Ended-to-Differential Conversion
200Ω
0
200Ω
–5
5582 F04
Figure 4. Differential Input Configuration
Due to the high input impedance of the LTC5582, a narrow
band L-C matching network can be also used to convert a
single-ended input to differential signal as shown in Figure
5. By this means, the sensitivity and overall linear dynamic
range of the detector will be very similar to the one using 1:8
RF input balun. The conversion gain is strongly dependent
on the loss (or Q) of the matching network, particularly at
high frequency. The lower the Q, the lower the conversion
gain. However, the matching bandwidth is correspondingly
wider. The following formulas are provided to calculate the
input matching network for single-ended-to-differential
conversion at low RF frequency (i.e., below 1GHz).
CS1 = CS2 =
1
2.25 • 10
=
fc
πfc 50RIN
50RIN 2.25 • 1010
LM =
=
2πfc
fc
9
(pF )
RETURN LOSS (dB)
IN–
–10
–15
–20
–25
–30
0 100 200 300 400 500 600 700 800 900 1000
FREQUENCY (MHz)
5582 F06
Figure 6. RF Input Return Loss
2.8
2.4
OUTPUT VOLTAGE (V)
4
LM
66nH
CS2
6.8pF
50pF
T1
1:8
TO IN+
RF INPUT
SINGLE-ENDED-TODIFFERENTIAL INPUTS
2.0
1.6
SINGLE-ENDED
1.2
0.8
(nH)
where RIN is the differential input resistance (400Ω) and
fc is the center RF operating frequency.
As an example, Figure 6 shows that good input return
loss is achieved from 300MHz to 400MHz when Cs1= Cs2
= 6.8pF and LM = 66nH. Figure 7 show the sensitivity is
also improved by 8dB at 350MHz while the dynamic range
remains the same.
0.4
–75 –65 –55 –45 –35 –25 –15
RF INPUT POWER (dBm)
–5
5
5582 F07
Figure 7. Output Voltage vs RF Input Power
Although these equations give a good starting point,
it is usually necessary to adjust the component values
after building and testing the circuit. As the RF operating
frequency increases, the real values of CS1, CS2, LM will
deviate from the above equations due to parasitics of the
components, device and PCB layout.
For a 50Ω input termination, the approximate RF input
power range of the LTC5582 is from –60dBm to 2dBm,
5582f
11
LTC5582
The sensitivity of LTC5582 is dictated by the broadband
input noise power that also determines the output DC
offset voltage. When the inputs are terminated differently,
the DC output voltage may vary slightly. When the input
noise power is minimized, the DC offset voltage is also
reduced to the minimum. And the detector’s sensitivity
and dynamic range will be improved accordingly.
External Filtering (FLTR) Capacitor
This pin is internally biased at VCC – 0.43V via a 1.2k
resistor from the voltage supply, VCC. To assure stable
operation of the LTC5582, an external capacitor C3 with
a value of 8nF or higher is required to connect from the
FLTR Pin to VCC to avoid an abnormal start-up condition.
Don’t connect this filtering capacitor to ground or any
other low voltage reference at any time.
This external capacitor value has a dominant effect on the
output transient response. The lower the capacitance, the
faster the output rise and fall times. For signals with AM
content such as W-CDMA, significant ripple can be observed when the loop bandwidth set by C3 is close to the
modulation bandwidth of the signal. A 4-carrier W‑CDMA
RF signal is used as an example in this case. The trade-offs
of the residual ripple vs the output transient times are as
shown in Figure 8.
In general, the LTC5582 output ripple remains relatively
constant regardless of the RF input power level for a fixed
C3 and modulation format of the RF signal. Typically, C3
must be selected to smooth out the ripple to achieve the
desired accuracy of RF power measurement.
Output Interface
The output buffer amplifier of the LTC5582 is shown in
Figure 9. This Class AB buffer amplifier can source and
sink 5mA current to and from the load. The output impedance is determined primarily by the 100Ω series resistor
12
500
50
450
45
400
40
350
35
300
30
RIPPLE
250
25
FALL TIME
200
20
150
15
100
10
50
0
RISE TIME
0
200
400
600
800
FILTERNING CAPACITOR C3 (nF)
RISE TIME (µs)
even with high crest factor signals such as a 4-carrier
W‑CDMA waveform, and the minimum detectable RF power
level varies as the input RF frequency increases. The linear
dynamic range can also be shifted to suit a particular application need. By simply inserting an attenuator in front
of the RF input, the power range is shifted higher by the
amount of the attenuation.
RIPPLE (mVP-P), FALL TIME (µs)
Applications Information
5
0
1000
5582 F08
Figure 8. Residual Ripple, Output Transient Times vs
Filtering Capacitor C3
LTC5582
VCC
INPUT
100Ω
OUT
RSS
VOUT
CLOAD
5582 F09
Figure 9. Simplified Schematic of the Output Interface
connected to the output of the buffer amplifier inside the
chip. This will prevent overstress on internal devices in
the event that the output is shorted to ground.
The –3dB small-signal bandwidth of the buffer amplifier is
about 22.4MHz and the full-scale rise/fall time can be as
fast as 80ns, limited by the slew rate of the internal circuit
instead. When the output is resistively terminated or open,
the fastest output transient response is achieved when a
large signal is applied to the RF input. The rise time of the
LTC5582 is about 90ns and the fall time is 5µs, respectively,
for full-scale pulsed RF input power when C3 = 8nF. The
speed of the output transient response is dictated mainly
by the filtering capacitor C3 (at least 8nF) at the FLTR Pin.
See the detailed output transient response in the Typical
Performance Characteristics section. When the RF input
has AM content, residual ripple may be present at the
output depending upon the low frequency content of the
modulated RF signal. This ripple can be reduced with a
larger filtering capacitor C3 at the expense of a slower
transient response.
5582f
LTC5582
Applications Information
CLOAD ≤ 5mA •
5mA •
allowable additional time
=
1.7 V
0.25µs
= 735pF
1.7 V
Once CLOAD is determined, RSS can be chosen properly
to form a RC low-pass filter with a corner frequency of
1/[2π(RSS + 100) • CLOAD].
Temperature Compensation of Logarithmic Intercept
The simplified interface schematic of the intercept temperature compensation is shown in Figure 10. The adjustment
of the output voltage can be described by the following
equation with respect to the ambient temperature:
ΔVOUT = –TC1 • (TA – TNOM) – TC2 • (TA – TNOM)2–
detV1 – detV2
where TC1 and TC2 are the 1st-order and 2nd-order
temperature compensation coefficients, respectively; TA
is the actual ambient temperature; and TNOM is the reference room temperature; detV1 and detV2 are the output
voltage variations when RT1 and RT2 are not set to zero at
room temperature. The temperature coefficients TC1 and
LTC5582
VCC
RT1 OR RT2
250Ω
RT1 OR RT2
5582 F10
Figure 10. Simplified Interface Circuit Schematic of the
Control Pins RT1 and RT2
When Pins RT1 and RT2 are shorted to ground, the temperature compensation circuit is disabled automatically.
Table 2 lists the suggested RT1 and RT2 values at various
RF frequencies for the best output performance over
temperature.
1.2
120
1.0
100
TC1
0.8
80
0.6
60
0.4
40
0.2
0
20
detV1
5
10
15
20
25
RT1 (kΩ)
detV1 (mV)
In general, the rise time of the LTC5582 is much shorter
than the fall time. However, when the output RC filter is
used, the rise time can be dominated by the time constant
of this filter. Accordingly, the rise time becomes very similar
to the fall time. Although the maximum sinking capability
of the LTC5582 is 5mA, it is recommended that the output
load resistance should be greater than 1.2k in order to
achieve the full output voltage swing.
TC2 are shown as functions of the tuning resistors RT1
and RT2 in Figures 11 and 12, respectively.
TC1 (mV/°C)
Since the output buffer amplifier of the LTC5582 is capable
of driving an arbitrary capacitive load, the residual ripple
can be further filtered at the output with a series resistor
RSS and a large shunt capacitor CLOAD. See Figure 9. This
lowpass filter also reduces the output noise by limiting
the output noise bandwidth. When this RC network is
designed properly, a fast output transient response can
be maintained with a reduced residual ripple. For example,
we can estimate CLOAD with an output voltage swing of
1.7V at 2140MHz. In order not to allow the maximum
5mA souring current to limit the fall time (about 5μs), the
maximum value of CLOAD can be chosen as follows:
30
35
0
40
5582 F11
Figure 11. 1st-Order Temperature Compensation Coefficient
TC1 vs RT1 Value
Table 2. Suggested RT1 and RT2 Values for Optimal Temperature
Performance vs RF Frequency
FREQUENCY (MHz)
RT1 (kΩ)
RT2 (kΩ)
450
12
2
880
12
2
2140
0
2
2700
0
1.6
3600
0
1.6
5800
0
3
5582f
13
LTC5582
20
200
16
160
12
120
TC2
8
80
4
0
40
detV2
0
1
2
3
4
5
RT2 (kΩ)
Enable Interface
detV2 (mV)
TC2 (µV/°C)
Applications Information
6
7
8
0
5582 F12
Figure 12. 2nd-Order Temperature Compensation Coefficient
TC2 vs RT2 Value
VCC
EN
52k
52k
5582 F13
Figure 13. Enable Pin Simplified Circuit
A simplified schematic of the EN Pin interface is shown
in Figure 13. The enable voltage necessary to turn on the
LTC5582 is 1V. To disable or turn off the chip, this voltage should be below 0.4V. It is important that the voltage
applied to the EN pin should never exceed VCC by more
than 0.3V. Otherwise, the supply current may be sourced
through the upper ESD protection diode connected at the
EN pin. Under no circumstances should voltage be applied
to the EN Pin before the supply voltage is applied to the
VCC pin. If this occurs, damage to the IC may result.
Supply Voltage Ramping
Fast ramping of the supply voltage can cause a current
glitch in the internal ESD protection circuits. Depending on
the supply inductance, this could result in a supply voltage
overshooting at the initial transient that exceeds the maximum rating. A supply voltage ramp time of greater than
1ms is recommended. In case this voltage ramp time is not
controllable, a small (i.e., 1.5Ω) series resistor should be
inserted in-between VCC Pin and the supply voltage source
to mitigate the problem and self-protect the IC. The R1
shown in Figure 1 is served for this purpose.
5582f
14
LTC5582
Package Description
DD Package
10-Lead Plastic DFN (3mm × 3mm)
(Reference LTC DWG # 05-08-1699 Rev B)
0.70 p0.05
3.55 p0.05
1.65 p0.05
2.15 p0.05 (2 SIDES)
PACKAGE
OUTLINE
0.25 p 0.05
0.50
BSC
2.38 p0.05
(2 SIDES)
RECOMMENDED SOLDER PAD PITCH AND DIMENSIONS
3.00 p0.10
(4 SIDES)
R = 0.125
TYP
6
0.40 p 0.10
10
1.65 p 0.10
(2 SIDES)
PIN 1
TOP MARK
(SEE NOTE 6)
0.200 REF
0.75 p0.05
0.00 – 0.05
5
1
(DD) DFN REV B 0309
0.25 p 0.05
0.50 BSC
2.38 p0.10
(2 SIDES)
BOTTOM VIEW—EXPOSED PAD
NOTE:
1. DRAWING TO BE MADE A JEDEC PACKAGE OUTLINE M0-229 VARIATION OF (WEED-2).
CHECK THE LTC WEBSITE DATA SHEET FOR CURRENT STATUS OF VARIATION ASSIGNMENT
2. DRAWING NOT TO SCALE
3. ALL DIMENSIONS ARE IN MILLIMETERS
4. DIMENSIONS OF EXPOSED PAD ON BOTTOM OF PACKAGE DO NOT INCLUDE
MOLD FLASH. MOLD FLASH, IF PRESENT, SHALL NOT EXCEED 0.15mm ON ANY SIDE
5. EXPOSED PAD SHALL BE SOLDER PLATED
6. SHADED AREA IS ONLY A REFERENCE FOR PIN 1 LOCATION ON THE
TOP AND BOTTOM OF PACKAGE
5582f
Information furnished by Linear Technology Corporation is believed to be accurate and reliable.
However, no responsibility is assumed for its use. Linear Technology Corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights.
15
LTC5582
Typical Application
40MHz to 6GHz Infrastructure Power Amplifier Level Control
DIRECTIONAL
COUPLER
PA
RFIN
3.3V
100nF
1
50Ω
270pF
68Ω
2
3
4
1nF
5
FLTR
VCC
IN+
LTC5582
EN
DEC
RT1
IN–
RT2
GND
OUT
EXPOSED PAD
11
1µF
10
DIGITAL
POWER
CONTROL
9
8
7
6
1nF
OUT
ADC
5582 TA02
Related Parts
PART NUMBER
DESCRIPTION
RF Power Detectors
LTC5505
RF Power Detectors with >40dB Dynamic Range
LTC5507
100kHz to 1000MHz RF Power Detector
LTC5508
300MHz to 7GHz RF Power Detector
LTC5509
300MHz to 3GHz RF Power Detector
LTC5530
300MHz to 7GHz Precision RF Power Detector
LTC5531
300MHz to 7GHz Precision RF Power Detector
LTC5532
300MHz to 7GHz Precision RF Power Detector
LT5534
50MHz to 3GHz Log RF Power Detector with 60dB
Dynamic Range
LTC5536
Precision 600MHz to 7GHz RF Power Detector
with Fast Comparator Output
LT5537
Wide Dynamic Range Log RF/IF Detector
LT5538
75dB Dynamic Range 3.8GHz Log RF Power
Detector
LT5570
60dB Dynamic Range RMS Detector
LT5581
6GHz RMS Power Detector with 40dB Dynamic
Range
Infrastructure
LTC5540/LTC5541/ 600MHz to 4GHz High Dynamic Range
LTC5542/LTC5543 Downconverting Mixer
LT5579
1.5GHz to 3.8GHz High Linearity Upconverting
Mixer
LTC5598
5MHz to 1600MHz High Linearity Direct
Quadrature Modulator
COMMENTS
300MHz to 3GHz, Temperature Compensated, 2.7V to 6V Supply
100kHz to 1GHz, Temperature Compensated, 2.7V to 6V Supply
44dB Dynamic Range, Temperature Compensated, SC70 Package
36dB Dynamic Range, Low Power Consumption, SC70 Package
Precision VOUT Offset Control, Shutdown, Adjustable Gain
Precision VOUT Offset Control, Shutdown, Adjustable Offset
Precision VOUT Offset Control, Adjustable Gain and Offset
±1dB Output Variation over Temperature, 38ns Response Time, Log Linear
Response
25ns Response Time, Comparator Reference Input, Latch Enable Input,
–26dBm to +12dBm Input Range
Low Frequency to 1GHz, 83dB Log Linear Dynamic Range
±0.8dB Accuracy Over Temperature
40MHz to 2.7GHz, ±0.5dB Accuracy Over Temperature
±1dB Accuracy Over Temperature, Log Linear Response, 1.4mA at 3.3V
IIP3 = 26dBm, 8dB Conversion Gain, <10dB NF, 3.3V, 190mA Supply Operation
27.3dBm OIP3 at 2.14GHz, 9.9dB NF, 2.6dB Conversion Gain, –35dBm LO
Leakage
27.7dBm OIP3 at 140MHz, –161.2dBm/Hz Noise Floor, 0.5VDC Baseband
Interface, –55dBm LO Leakage and 50.4dBc Image Rejection at 140MHz
5582f
16 Linear Technology Corporation
1630 McCarthy Blvd., Milpitas, CA 95035-7417
(408) 432-1900
●
FAX: (408) 434-0507 ● www.linear.com
LT 0510 • PRINTED IN USA
 LINEAR TECHNOLOGY CORPORATION 2010
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