LMH2110TM/NOPB [TI]

具有 45dB 动态范围的 8GHz 对数 RMS 功率检测器 | YFQ | 6 | -40 to 85;


型号：	LMH2110TM/NOPB
厂家：	TEXAS INSTRUMENTS
描述：	具有 45dB 动态范围的 8GHz 对数 RMS 功率检测器 \| YFQ \| 6 \| -40 to 85 电信电信集成电路
文件：	总36页 (文件大小：938K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

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LMH2110

SNWS022D –JANUARY 2010–REVISED JUNE 2015

LMH2110 8-GHz Logarithmic RMS Power Detector with 45-dB Dynamic Range

1 Features

3 Description

The LMH2110 is a 45-dB Logarithmic RMS power

detector particularly suited for accurate power

measurement of modulated RF signals that exhibit

large peak-to-average ratios; that is, large variations

of the signal envelope. Such signals are encountered

in W-CDMA and LTE cell phones. The RMS

•

Wide Supply Range from 2.7 V to 5 V

Logarithmic Root Mean Square Response

45-dB Linear-in-dB Power Detection Range

Multi-Band Operation from 50 MHz to 8 GHz

LOG Conformance Better than ±0.5 dB

Highly Temperature Insensitive, ±0.25 dB

Modulation Independent Response, 0.08 dB

Minimal Slope and Intercept Variation

Shutdown Functionality

•

measurement topology inherently ensures

modulation insensitive measurement.

The device has an RF frequency range from 50 MHz

to 8 GHz. It provides an accurate, temperature and

supply insensitive output voltage that relates linearly

to the RF input power in dBm. The LMH2110 device

has excellent conformance to a logarithmic response,

enabling easy integration by using slope and intercept

only, reducing calibration effort significantly. The

device operates with a single supply from 2.7 V to

5 V. The LMH2110 has an RF power detection range

from –40 dBm to 5 dBm and is ideally suited for use

Tiny 6-Bump DSBGA Package

2 Applications

•

Multi-Mode, Multi-Band RF Power Control

–

GSM/EDGE

CDMA/CDMA2000

W-CDMA

in combination with

Alternatively, a resistive divider can be used.

directional coupler.

OFDMA

The device is active for EN = High; otherwise, it is in

a low power-consumption shutdown mode. To save

power and prevent discharge of an external filter

capacitance, the output (OUT) is high-impedance

during shutdown.

LTE

•

Infrastructure RF Power Control

space

Device Information⁽¹⁾

PART NUMBER

PACKAGE

BODY SIZE (MAX)

LMH2110

DSBGA (6)

1.27 mm × 0.87 mm

(1) For all available packages, see the orderable addendum at

the end of the data sheet.

Typical Application Circuit

Output Voltage and Log Conformance Error vs.

RF Input Power at 1900 MHz

COUPLER

ANTENNA

2.4

2.0

1.6

1.2

0.8

0.4

0.0

50 :

-40°C

25°C

VDD

RFIN

OUT

-1

-2

-3

85°C

LMH2110

ADC

B2, C1

GND

-40

-30

-20

-10

RF INPUT POWER (dBm)

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.

LMH2110

SNWS022D –JANUARY 2010–REVISED JUNE 2015

www.ti.com

Table of Contents

7.3 Feature Description................................................. 16

7.4 Device Functional Modes........................................ 20

Application and Implementation ........................ 21

8.1 Application Information............................................ 21

8.2 Typical Applications ................................................ 21

Power Supply Recommendations...................... 29

Features.................................................................. 1

Applications ........................................................... 1

Description ............................................................. 1

Revision History..................................................... 2

Pin Configuration and Functions......................... 3

Specifications......................................................... 4

6.1 Absolute Maximum Ratings ...................................... 4

6.2 ESD Ratings.............................................................. 4

6.3 Recommended Operating Conditions....................... 4

6.4 Thermal Information.................................................. 4

10 Layout................................................................... 29

10.1 Layout Guidelines ................................................. 29

10.2 Layout Example .................................................... 29

11 Device and Documentation Support ................. 30

11.1 Community Resources.......................................... 30

11.2 Trademarks........................................................... 30

11.3 Electrostatic Discharge Caution............................ 30

11.4 Glossary................................................................ 30

6.5 2.7-V and 4.5-V DC and AC Electrical

Characteristics ........................................................... 5

6.6 Timing Requirements................................................ 8

6.7 Typical Characteristics.............................................. 9

Detailed Description ............................................ 16

7.1 Overview ................................................................. 16

7.2 Functional Block Diagram ....................................... 16

12 Mechanical, Packaging, and Orderable

Information ........................................................... 30

4 Revision History

NOTE: Page numbers for previous revisions may differ from page numbers in the current version.

Changes from Revision C (March 2013) to Revision D

Page

•

Added Pin Configuration and Functions section, ESD Ratings table, Feature Description section, Device Functional

Modes, Application and Implementation section, Power Supply Recommendations section, Layout section, Device

and Documentation Support section, and Mechanical, Packaging, and Orderable Information section .............................. 1

Changes from Revision B (October 2013) to Revision C

Page

•

Changed layout of National Data Sheet to TI format ........................................................................................................... 29

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SNWS022D –JANUARY 2010–REVISED JUNE 2015

5 Pin Configuration and Functions

YFQ Package

6-Bump DSBGA

Top View

VDD

OUT

GND

RFIN

GND

Pin Functions

TYPE

DESCRIPTION

NUMBER

NAME

VDD

Power Supply

Output

Positive supply voltage.

OUT

Ground referenced detector output voltage.

RF input signal to the detector, internally terminated with 50 Ω.

Power Ground. May be left floating in case grounding is not feasible.

Power Ground.

RFIN

GND

Analog Input

Power Supply

The device is enabled for EN = High, and in shutdown mode for EN = Low. EN

must be < 2.5 V to have low I_EN. For EN > 2.5 V, I_ENincreases slightly, while

device is still functional. Absolute maximum rating for EN = 3.6 V.

Logic Input

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SNWS022D –JANUARY 2010–REVISED JUNE 2015

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6 Specifications

6.1 Absolute Maximum Ratings

over operating free-air temperature range (unless otherwise noted)⁽¹⁾⁽²⁾

MIN

MAX

5.5

UNIT

Supply voltage

RF input

V_BAT– GND

Input power

DC voltage

dBm

Enable input voltage

GND – 0.4 < V_ENand V_EN< Min (V_DD– 0.4 V, 3.6 V)

Junction temperature⁽³⁾

150

260

°C

Maximum lead temperature (Soldering,10 sec)

Storage temperature, T_stg

−65

150

(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.

(2) If Military/Aerospace specified devices are required, contact the Texas Instruments Sales Office/ Distributors for availability and

specifications.

(3) The maximum power dissipation is a function of T_J(MAX), R_θJA. The maximum allowable power dissipation at any ambient temperature is

P_D= (T_J(MAX)– T_A)/R_θJA. All numbers apply for packages soldered directly into a PC board.

6.2 ESD Ratings

VALUE

±2000

±1000

±200

UNIT

Human-body model (HBM), per ANSI/ESDA/JEDEC JS-001⁽¹⁾

Charged-device model (CDM), per JEDEC specification JESD22-C101⁽²⁾

Machine Model

Electrostatic

discharge

V_(ESD)

(1) JEDEC document JEP155 states that 500-V HBM allows safe manufacturing with a standard ESD control process.

(2) JEDEC document JEP157 states that 250-V CDM allows safe manufacturing with a standard ESD control process.

6.3 Recommended Operating Conditions

over operating free-air temperature range (unless otherwise noted)⁽¹⁾

MIN

MAX

UNIT

Supply voltage

2.7

−40

Operating temperature

RF frequency

°C

8000

MHz

dBm

RF input power

−40

(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.

6.4 Thermal Information

LMH2110

THERMAL METRIC⁽¹⁾

YFQ (DSBGA)

6 PINS

133.7

1.7

UNIT

R_θJA

R_θJC(top)

R_θJB

ψ_JT

Junction-to-ambient thermal resistance

°C/W

Junction-to-case (top) thermal resistance

Junction-to-board thermal resistance

22.6

Junction-to-top characterization parameter

Junction-to-board characterization parameter

5.7

ψ_JB

22.2

(1) For more information about traditional and new thermal metrics, see the Semiconductor and IC Package Thermal Metrics application

report, SPRA953.

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SNWS022D –JANUARY 2010–REVISED JUNE 2015

6.5 2.7-V and 4.5-V DC and AC Electrical Characteristics

Unless otherwise specified: all limits are ensured to T_A= 25°C, V_BAT= 2.7 V and 4.5 V (worst of the 2 is specified),

RF_IN= 1900 MHz CW (Continuous Wave, unmodulated).⁽¹⁾

PARAMETER

TEST CONDITIONS

MIN⁽²⁾

TYP⁽³⁾

MAX⁽²⁾

UNIT

SUPPLY INTERFACE

Active mode: EN = HIGH, no signal present at RF_IN

3.7

2.9

4.8

5.5

5.9

Active mode: EN = HIGH, no signal present at RF_IN

Limits apply at temperature extremes.

V_BAT= 2.7 V

V_BAT= 4.5 V

V_BAT= 2.7 V

3.7

4.6

4.7

5.7

Shutdown: EN = LOW, no signal

present at RF_IN

μA

Shutdown: EN = LOW, no signal

present at RF_IN

I_BAT

Supply current

V_BAT= 4.5 V

6.1

Limits apply at temperature extremes.

V_BAT= 2.7V

V_BAT= 4.5 V

V_BAT= 2.7 V

V_BAT= 4.5 V

3.5

4.6

4.7

5.7

EN = Low, RF_IN= 0 dBm, 1900 MHz

μA

EN = Low, RF_IN= 0 dBm, 1900 MHz

Limits apply at temperature extremes.

6.1

RF_IN= −10 dBm, 1900 MHz, 2.7V < V_BAT< 5 V

Power Supply Rejection

Ratio⁽⁴⁾

PSRR

RF_IN= −10 dBm, 1900 MHz, 2.7V < V_BAT< 5 V

Limits apply at temperature extremes.

LOGIC ENABLE INTERFACE

EN logic low input level

V_LOW

Limits apply at temperature extremes.

0.6

(Shutdown mode)

V_HIGH

I_EN

INPUT/OUTPUT INTERFACE

EN logic high input level Limits apply at temperature extremes.

1.1

Current into EN pin

Limits apply at temperature extremes.

R_IN

Input resistance

Ω

No input signal

1.5

Minimum output voltage

(pedestal)

V_OUT

No input signal, limits apply at temperature extremes

EN = High, RF_IN= –10 dBm, 1900 MHz, I_LOAD= 1

mA, DC measurement

0.2

EN = High, RF_IN= –10 dBm, 1900 MHz, I_LOAD= 1

mA,

DC measurement, limits apply at temperature

extremes.

R_OUT

Output impedance

Ω

Sinking, RF_IN= –10 dBm, OUT connected to 2.5 V

Limits apply at temperature extremes.

Output short circuit

current

I_OUT

Sourcing, RF_IN= –10 dBm, OUT connected to GND

Limits apply at temperature extremes.

Output leakage current in EN = Low, OUT connected to 2 V

I_OUT,SD

e_n

shutdown mode

Limits apply at temperature extremes.

RF_IN= −10 dBm, 1900 MHz, output spectrum at 10

kHz

Output referred noise⁽⁴⁾

µV√Hz

µV_RMS

Integrated output referred Integrated over frequency band

noise⁽⁴⁾

1 kHz – 6.5 kHz, RF_IN= –10 dBm, 1900 MHz

V_N

210

(1) 2.7-V and 4.5-V DC and AC Electrical Characteristics 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 T_J= T_A. Parametric performance is not ensured in the

2.7-V and 4.5-V DC and AC Electrical Characteristics under conditions of internal self-heating where T_J> T_A.

(2) All limits are specified by test or statistical analysis.

(3) Typical values represent the most likely parametric norm as determined at the time of characterization. Actual typical values may vary

over time and depend on the application and configuration. The typical values are not tested and are not specified on shipped

production material.

(4) This parameter is specified by design and/or characterization and is not tested in production.

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2.7-V and 4.5-V DC and AC Electrical Characteristics (continued)

Unless otherwise specified: all limits are ensured to T_A= 25°C, V_BAT= 2.7 V and 4.5 V (worst of the 2 is specified),

RF_IN= 1900 MHz CW (Continuous Wave, unmodulated).⁽¹⁾

PARAMETER

TEST CONDITIONS

MIN⁽²⁾

TYP⁽³⁾

MAX⁽²⁾

UNIT

RF DETECTOR TRANSFER

RF_IN= 50 MHz (fit range –20 dBm to –10 dBm)⁽⁵⁾

Minimum power level,

P_MIN

bottom end of dynamic

range

Log conformance error within ±1 dB

–39

dBm

Maximum power level,

top end of dynamic range

P_MAX

Log conformance error within ±1 dB

At P_MIN

V_MIN

Minimum output voltage

1.96

44.3

–38.3

V_MAX

K_SLOPE

P_INT

Maximum output voltage At P_MAX

Logarithmic slope

42.2

46.4 mV/dB

Logarithmic Intercept

–38.6

–38.0

dBm

±1-dB Log conformance error (E_LC

)

Limits apply at temperature extremes.

±3-dB Log Conformance Error (E_LC

±3-dB Log conformance error (E_LC

)

Dynamic Range for

specified accuracy

)

Limits apply at temperature extremes.

±0.5-dB input referred variation over temperature

(E_VOT), from P_MIN

Limits apply at temperature extremes.

RF DETECTOR TRANSFER

RF_IN= 900 MHz (fit range –20 dBm to –10 dBm)⁽⁵⁾

Minimum power level,

P_MIN

bottom end of dynamic

range

Log conformance error within ±1 dB

–38

dBm

Maximum power level,

top end of dynamic range

P_MAX

Log conformance error within ±1 dB

At P_MIN

V_MIN

Minimum output voltage

1.58

43.9

–37

V_MAX

K_SLOPE

P_INT

Maximum output voltage At P_MAX

Logarithmic slope

41.8

46 mV/dB

–36.7 dBm

Logarithmic intercept

–37.4

±1-dB Log conformance error (E_LC

)

Limits apply at temperature extremes.

±3-dB Log conformance error (E_LC

)

Limits apply at temperature extremes.

Dynamic range for

specified accuracy

±0.5-dB Input referred variation over temperature

(E_VOT), from P_MIN

Limits apply at temperature extremes.

±0.3-dB Error for a 1dB Step (E1dB STEP)

Limits apply at temperature extremes.

±1-dB Error for a 10dB Step (E10dB 30 STEP)

Limits apply at temperature extremes.

Input-referred variation

due to modulation

W-CDMA Release 6/7/8,

–38 dBm < RF_IN< –5 dBm

E_MOD

0.08

0.19

LTE, –38 dBm < RF_IN< –5 dBm

(5) All limits are specified by design and measurements which are performed on a limited number of samples. Limits represent the mean

±3–sigma values. The typical value represents the statistical mean value.

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2.7-V and 4.5-V DC and AC Electrical Characteristics (continued)

Unless otherwise specified: all limits are ensured to T_A= 25°C, V_BAT= 2.7 V and 4.5 V (worst of the 2 is specified),

RF_IN= 1900 MHz CW (Continuous Wave, unmodulated).⁽¹⁾

PARAMETER

TEST CONDITIONS

MIN⁽²⁾

TYP⁽³⁾

MAX⁽²⁾

UNIT

RF DETECTOR TRANSFER

RF_IN= 1900 MHz (fit range –20 dBm to –10 dBm)⁽⁵⁾

Minimum power level,

P_MIN

bottom end of dynamic

range

Log conformance error within ±1 dB

–36

dBm

Maximum power level,

top end of dynamic range

P_MAX

Log conformance error within ±1 dB

At P_MIN

V_MIN

Minimum output voltage

1.5

V_MAX

K_SLOPE

P_INT

maximum output voltage At P_MAX

Logarithmic slope

41.8

43.9

–35.1

46.1 mV/dB

–34.7 dBm

Logarithmic Intercept

–35.5

±1-dB Log conformance error (E_LC

Limits apply at temperature extremes.

)

±3-dB Log conformance Error (E_LC

±3-dB Log conformance error (E_LC

Limits apply at temperature extremes.

)

±0.5-dB Input referred variation over temperature

(E_VOT), from P_MIN

Limits apply at temperature extremes.

Dynamic range for

specified accuracy

±0.3-dB error for a 1-dB Step (E1dB STEP)

Limits apply at temperature extremes.

±1-dB error for a 10-dB Step (E10-dB 30 STEP)

Limits apply at temperature extremes.

W-CDMA Release 6/7/8,

–38 dBm < RF_IN< –5 dBm

0.09

0.18

Input-referred variation

due to modulation

E_MOD

LTE, –38 dBm < RF_IN< –5 dBm

RF_IN= 3500 MHz, fit range –15 dBm to –5 dBm⁽⁵⁾

Minimum power level,

P_MIN

bottom end of dynamic

range

Log conformance error within ±1 dB

–31

dBm

Maximum power level,

top end of dynamic range

P_MAX

Log conformance error within ±1 dB

At P_MIN

V_MIN

Minimum output voltage

1.52

V_MAX

K_SLOPE

P_INT

Maximum output voltage At P_MAX

Logarithmic slope

41.8

46.1 mV/dB

Logarithmic Intercept

–30.5

–29.7

–28.8

dBm

±1-dB Log conformance error (E_LC

)

Limits apply at temperature extremes.

±3-dB Log conformance error (E_LC

)

Dynamic range for

specified accuracy

Limits apply at temperature extremes.

±0.5-dB Input referred variation over temperature

(E_VOT), from P_MIN

Limits apply at temperature extremes.

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2.7-V and 4.5-V DC and AC Electrical Characteristics (continued)

Unless otherwise specified: all limits are ensured to T_A= 25°C, V_BAT= 2.7 V and 4.5 V (worst of the 2 is specified),

RF_IN= 1900 MHz CW (Continuous Wave, unmodulated).⁽¹⁾

PARAMETER

TEST CONDITIONS

MIN⁽²⁾

TYP⁽³⁾

MAX⁽²⁾

UNIT

RF_IN= 5800 MHz, fit range –20 dBm to 3 dBm⁽⁵⁾

Minimum power level,

P_MIN

bottom end of dynamic

range

Log conformance error within ±1 dB

–22

dBm

Maximum power level,

top end of dynamic range

P_MAX

Log conformance error within ±1 dB

At P_MIN

V_MIN

Minimum output voltage

1.34

44.8

–21

V_MAX

K_SLOPE

P_INT

Maximum output voltage At P_MAX

Logarithmic slope

42.5

–22

47.1 mV/dB

Logarithmic Intercept

–19.9

dBm

±1-dB Log conformance error (E_LC

)

Limits apply at temperature extremes.

±3-dB Log conformance error (E_LC

)

Dynamic range for

specified accuracy

±3-dB Log conformance error (E_LC

)

Limits apply at temperature extremes.

±0.5-dB Input referred variation over temperature

(E_VOT), from P_MIN

Limits apply at temperature extremes.

6.6 Timing Requirements

MIN

NOM

MAX

UNIT

Turnon time from shutdown

t_ON

µs

RF_IN= –10 dBm, 1900 MHz, EN LOW-HIGH transition to OUT at 90%

Rise time⁽¹⁾

t_R

t_F

2.2

µs

Signal at RF_INfrom –20 dBm to 0 dBm, 10% to 90%, 1900 MHz

(1)

Fall time

Signal at RF_INfrom 0 dBm to –20 dBm, 90% to 10%, 1900 MHz

(1) This parameter is specified by design and/or characterization and is not tested in production.

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6.7 Typical Characteristics

Unless otherwise specified: T_A= 25°C, V_BAT= 2.7 V, RF_IN= 1900 MHz CW (Continuous Wave, unmodulated). Specified

errors are input referred.

EN = LOW

EN = HIGH

85°C

25°C

-40°C

25°C

85°C

-40°C

SUPPLY VOLTAGE (V)

Figure 1. Supply Current vs. Supply Voltage (Active)

Figure 2. Supply Current vs. Supply Voltage (Shutdown)

85°C

25°C

85°C

-40°C

25°C

-40°C

-40

0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2

-30

-20

-10

ENABLE VOLTAGE (V)

RF INPUT POWER (dBm)

Figure 4. Supply Current vs. RF Input Power

Figure 3. Supply Current vs. Enable Voltage (EN)

-40°C

25°C

-40°C

25°C

85°C

OUT = 2.5V

RFin = 1900 MHz

OUT = 0V

RFin = 1900 MHz

-10 10

RF INPUT POWER (dBm)

-40

-30

-20

-30

-20

-10 0 10

RF INPUT POWER (dBm)

Figure 5. Sourcing Output Current vs. RF Input Power

Figure 6. Sinking Output Current vs. RF Input Power

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Typical Characteristics (continued)

Unless otherwise specified: T_A= 25°C, V_BAT= 2.7 V, RF_IN= 1900 MHz CW (Continuous Wave, unmodulated). Specified

errors are input referred.

100

-25

-50

-75

-50

-100

-75

MEASURED ON BUMP

-100

10M

100M

10G

100

10k

100k

FREQUENCY (Hz)

Figure 7. RF Input Impedance vs. Frequency,

Resistance (R) and Reactance (X)

Figure 8. Power Supply Rejection Ratio vs. Frequency

-40°C

85°C

25°C

10M

100M

10G

FREQUENCY (Hz)

Figure 9. Output Voltage Noise vs. Frequency

Figure 10. Log Slope vs. Frequency

-20

2.4

2.0

1.6

1.2

0.8

0.4

0.0

-24

-40°C

25°C

-28

85°C

-32

-1

-2

-3

85°C

25°C

-36

-40°C

-40

10M

100M

10G

-40

-30

-20

-10

FREQUENCY (Hz)

RF INPUT POWER (dBm)

Figure 11. Log Intercept vs. Frequency

Figure 12. Output Voltage and Log Conformance Error vs.

RF Input Power at 50 MHz

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Typical Characteristics (continued)

Unless otherwise specified: T_A= 25°C, V_BAT= 2.7 V, RF_IN= 1900 MHz CW (Continuous Wave, unmodulated). Specified

errors are input referred.

2.0

1.5

-40°C

1.0

-40°C

0.5

0.0

-0.5

-1.0

-1.5

-2.0

-1

-2

-3

85°C

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 14. Temperature Variation vs.

RF Input Power at 50 MHz

Figure 13. Log Conformance Error (50 Units) vs.

RF Input Power at 50 MHz

2.0

2.4

2.0

1.6

1.2

0.8

0.4

0.0

1.5

-40°C

1.0

0.5

-40°C

25°C

0.0

-0.5

-1.0

-1

85°C

-2

-1.5

-2.0

-40

-3

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 15. Temperature Variation (50 Units) vs.

RF Input Power at 50 MHz

Figure 16. Output Voltage and Log Conformance Error vs.

RF Input Power at 900 MHz

2.0

1.5

-40°C

1.0

-40°C

0.5

0.0

-0.5

-1

85°C

-1.0

85°C

-2

-3

-1.5

-2.0

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 18. Temperature Variation vs.

RF Input Power at 900 MHz

Figure 17. Log Conformance Error (50 Units) vs.

RF Input Power at 900 MHz

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Typical Characteristics (continued)

Unless otherwise specified: T_A= 25°C, V_BAT= 2.7 V, RF_IN= 1900 MHz CW (Continuous Wave, unmodulated). Specified

errors are input referred.

2.0

1.5

-40°C

25°C

1.0

85°C

0.5

0.0

-0.5

-1.0

-1.5

-2.0

-0.5

-1.0

-1.5

-2.0

-40°C

85°C

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 20. 1-dB Power Step Error vs.

RF Input Power at 900 MHz

Figure 19. Temperature Variation (50 Units) vs.

RF Input Power at 900 MHz

1.5

2.0

1.5

1.0

0.5

85°C

W-CDMA, REL8

0.5

0.0

W-CDMA, REL6

-0.5

-40°C

W-CDMA, REL7

-1.0

-1.5

-2.0

-1.0

-1.5

-40

-30

-20

-10

-40 -35 -30 -25 -20 -15 -10 -5

RF INPUT POWER (dBm)

Figure 22. W-CDMA Variation vs.

RF Input Power at 900 MHz

Figure 21. 10 dB Power Step Error vs.

RF Input Power at 900 MHz

1.5

2.4

2.0

1.6

1.2

0.8

0.4

0.0

20MHz, 100RB

1.0

-40°C

25°C

0.5

LTE, QPSK

0.0

-0.5

-1

LTE, 16QAM

85°C

-1.0

-2

LTE, 64QAM

-1.5

-40

-3

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 23. LTE Variation vs.

RF Input Power at 900 MHz

Figure 24. Output Voltage and Log Conformance Error vs.

RF Input Power at 1900 MHz

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Typical Characteristics (continued)

Unless otherwise specified: T_A= 25°C, V_BAT= 2.7 V, RF_IN= 1900 MHz CW (Continuous Wave, unmodulated). Specified

errors are input referred.

2.0

1.5

1.0

-40°C

85°C

0.5

0.0

-0.5

-1.0

-1.5

-2.0

-1

-2

-3

85°C

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 26. Temperature Variation vs.

RF Input Power at 1900 MHz

Figure 25. Log Conformance Error (50 Units) vs.

RF Input Power at 1900 MHz

2.0

1.5

1.0

-40°C

25°C

1.0

85°C

0.5

0.0

-0.5

-1.0

-1.5

-2.0

-0.5

-40°C

-1.0

85°C

-1.5

-2.0

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 28. 1-dB Power Step Error vs.

RF Input Power at 1900 MHz

Figure 27. Temperature Variation (50 Units) vs.

RF Input Power at 1900 MHz

1.5

2.0

1.5

1.0

W-CDMA, REL8

0.5

85°C

0.5

0.0

W-CDMA, REL6

-0.5

-40°C

-1.0

-1.5

-2.0

W-CDMA, REL7

-1.0

-1.5

-40

-30

-20

-10

-40 -35 -30 -25 -20 -15 -10 -5

RF INPUT POWER (dBm)

Figure 30. W-CDMA Variation vs.

RF Input Power at 1900 MHz

Figure 29. 10-dB Power Step Error vs.

RF Input Power at 1900 MHz

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Typical Characteristics (continued)

Unless otherwise specified: T_A= 25°C, V_BAT= 2.7 V, RF_IN= 1900 MHz CW (Continuous Wave, unmodulated). Specified

errors are input referred.

1.5

2.4

2.0

1.6

1.2

0.8

0.4

0.0

20MHz, 100RB

1.0

-40°C

0.5

25°C

LTE, QPSK

0.0

-0.5

-1.0

-1.5

-1

-2

-3

LTE, 16QAM

85°C

LTE, 64QAM

0 10

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 31. LTE Input referred Variation vs.

RF Input Power at 1900 MHz

Figure 32. Output Voltage and Log Conformance Error vs.

RF Input Power at 3500 MHz

2.0

1.5

1.0

-40°C

0.5

0.0

-0.5

-1

85°C

-1.0

-1.5

-2.0

85°C

-2

-3

-40

-30

-20

-10

-30

-20

-10

RF INPUT POWER (dBm)

Figure 34. Temperature Variation vs.

RF Input Power at 3500 MHz

Figure 33. Log Conformance Error (50 Units) vs.

RF Input Power at 3500 MHz

2.0

1.5

2.4

2.0

1.6

1.2

0.8

0.4

0.0

-40°C

1.0

-40°C

25°C

0.5

0.0

-0.5

-1

-2

-3

-1.0

85°C

-1.5

85°C

-2.0

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 35. Temperature Variation (50 Units) vs.

RF Input Power at 3500 MHz

Figure 36. Output Voltage and Log Conformance Error vs.

RF Input Power at 5800 MHz

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Typical Characteristics (continued)

Unless otherwise specified: T_A= 25°C, V_BAT= 2.7 V, RF_IN= 1900 MHz CW (Continuous Wave, unmodulated). Specified

errors are input referred.

2.0

1.5

-40°C

1.0

0.5

0.0

-0.5

-1.0

-1.5

-2.0

-1

-2

-3

85°C

-40

-30

-20

-10

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 38. Temperature Variation vs.

RF Input Power at 5800 MHz

Figure 37. Log Conformance Error (50 Units) vs.

RF Input Power at 5800 MHz

2.0

2.4

2.0

1.6

1.2

0.8

0.4

0.0

1.5

-40°C

1.0

0.5

25°C

-40°C

85°C

0.0

-0.5

-1.0

-1

-2

-3

85°C

-1.5

-2.0

-40

-30

-20

-10

-30

-20

-10

RF INPUT POWER (dBm)

Figure 39. Temperature Variation (50 Units) vs.

RF Input Power at 5800 MHz

Figure 40. Output Voltage and Log Conformance Error vs.

RF Input Power at 8000 MHz

2.0

1.5

1.0

-40°C

85°C

0.5

0.0

-0.5

-1.0

-1.5

-2.0

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 41. Temperature Variation vs.

RF Input Power at 8000 MHz

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7 Detailed Description

7.1 Overview

The LMH2110 is a high-performance logarithmic root mean square (RMS) power detector which measures the

actual power content of a signal. The device has a RF input power detection range from –40 dBm to 5 dBm and

provides accurate output voltage that relates linearly to the RF input power in dBm. This output voltage exhibits

high temperature insensitivity ranging ±0.25 dB.

The device has an internal low dropout linear regulator (LDO) making the device insensitive to input supply

variation and allowing operation from a wide input supply range from 2.7 V to 5 V. Additional features include

multi-band operation from 50 MHz to 8 GHz, shutdown functionality to save power, and minimal slope and

intercept variation.

7.2 Functional Block Diagram

VDD

LDO

Internal

Supply

EXP

V/I

RFIN

OUT

EXP

V/I

GND

B2,

7.3 Feature Description

7.3.1 Accurate Power Measurement

Detectors have evolved over the years along with the communication standards. Newer communication

standards like LTE and W-CDMA raise the need for more advanced accurate power detectors. To be able to

distinguish the various detector types it is important to understand the ideal power measurement and how a

power measurement is implemented.

Power is a metric for the average energy content of a signal. By definition it is not a function of the signal shape

over time. In other words, the power content of a 0-dBm sine wave is identical to the power content of a 0-dBm

square wave or a 0-dBm W-CDMA signal; all these signals have the same average power content.

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Feature Description (continued)

The average power can be described by Equation 1:

v(t)²

V_RMS

P =

dt =

where

•

T is the time interval over which is averaged

v(t) is the instantaneous voltage at time t

R is the resistance in which the power is dissipated

V_RMSis the equivalent RMS voltage

(1)

According to aforementioned formula for power, an exact power measurement can be done via measuring the

RMS voltage (V_RMS) of a signal. The RMS voltage is described by:

v(t)²dt

V_RMS

(2)

Implementing the exact formula for RMS can be challenging. A simplification can be made in determining the

average power when information about the waveform is available. If the signal shape is known, the relationship

between RMS value and, for instance, the peak value of the RF signal is also known. It thus enables a

measurement based on measuring peak voltage rather than measuring the RMS voltage. To calculate the RMS

value (and therewith the average power), the measured peak voltage is translated into an RMS voltage based on

the waveform characteristics. A few examples:

•

Sine wave: V_RMS= V_PEAK/ √2

Square wave: V_RMS= V_PEAK

Saw-tooth wave: V_RMS= V_PEAK/ √3

For more complex waveforms it is not always easy to determine the exact relationship between RMS value and

peak value. A peak measurement can then become impractical. An approximation can be used for the V_RMSto

V_PEAKrelationship but it can result in a less-accurate average power estimate.

Depending on the detection mechanism, power detectors may produce a slightly different output signal in

response to more complex waveforms, even though the average power level of these signals are the same. This

error is due to the fact that not all power detectors strictly implement the definition for signal power, being the

RMS of the signal. To cover for the systematic error in the output response of a detector, calibration can be

used. After calibration a look-up table corrects for the error. Multiple look-up tables can be created for different

modulation schemes.

7.3.2 Types of RF Detectors

The following is an overview of detectors based on their detection principle. Detectors discussed in detail are:

•

Peak Detectors

LOG Amp Detectors

RMS Detectors

7.3.2.1 Peak Detectors

A peak detector is one of the simplest types of detectors. According to the naming, the peak detector stores the

highest value arising in a certain time window. However, usually a peak detector is used with a relative long

holding time when compared to the carrier frequency and a relative short holding time with respect to the

envelope frequency. In this way a peak detector is used as AM demodulator or envelope tracker (Figure 42).

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Feature Description (continued)

PEAK

ENVELOPE

CARRIER

Figure 42. Peak Detection vs. Envelope Tracking

A peak detector usually has a linear response. An example of this is a diode detector (Figure 43). The diode

rectifies the RF input voltage and subsequently the RC filter determines the averaging (holding) time. The

selection of the holding time configures the diode detector for its particular application. For envelope tracking a

relatively small RC time constant is chosen, such that the output voltage tracks the envelope nicely. A

configuration with a relatively large time constant can be used for supply regulation of the power amplifier (PA).

Controlling the supply voltage of the PA can reduce power consumption significantly. The optimal mode of

operation is to set the supply voltage such that it is just above the maximum output voltage of the PA. A diode

detector with relative large RC time constant measures this maximum (peak) voltage.

REF

OUT

Figure 43. Diode Detector

Because peak detectors measure a peak voltage, their response is inherently depended on the signal shape or

modulation form as discussed in the previous section. Knowledge about the signal shape is required to

determine an RMS value. For complex systems having various modulation schemes, the amount of calibration

and look-up tables can become unmanageable.

7.3.2.2 LOG Amp Detectors

LOG Amp detectors are widely used RF power detectors for GSM and the early W-CDMA systems. The transfer

function of a LOG amp detector has a linear-in-dB response, which means that the output in volts changes

linearly with the RF power in dBm. This is convenient because most communication standards specify transmit

power levels in dBm as well. LOG amp detectors implement the logarithmic function by a piecewise linear

approximation. Consequently, the LOG amp detector does not implement an exact power measurement, which

implies a dependency on the signal shape. In systems using various modulation schemes calibration and lookup

tables might be required.

7.3.2.3 RMS Detectors

An RMS detector has a response that is insensitive to the signal shape and modulation form. This is because its

operation is based on exact determination of the average power, that is, it implements:

v(t)²dt

V_RMS

(3)

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Feature Description (continued)

RMS detectors are in particular suited for the newer communication standards like W-CDMA and LTE that exhibit

large peak-to-average ratios and different modulation schemes (signal shapes). This is a key advantage

compared to other types of detectors in applications that employ signals with high peak-to-average power

variations or different modulation schemes. For example, the RMS detector response to a 0-dBm modulated W-

CDMA signal and a 0-dBm unmodulated carrier is essentially equal. This eliminates the need for long calibration

procedures and large calibration tables in the baseband due to different applied modulation schemes.

7.3.3 LMH2110 RF Power Detector

For optimal performance of the LMH2110, the device must to be configured correctly in the application (see

Functional Block Diagram).

For measuring the RMS (power) level of a signal, the time average of the squared signal needs to be measured

as described in Accurate Power Measurement. This is implemented in the LMH2110 by means of a multiplier and

a low-pass filter in a negative-feedback loop. A simplified block diagram of the LMH2110 is depicted in Functional

Block Diagram. The core of the loop is a multiplier. The two inputs of the multiplier are fed by (i₁, i₂):

i₁= i_LF+ i_RF

i₂= i_LF– i_RF

(4)

where

•

i_LFis a current depending on the DC output voltage of the RF detector, and

i_RFis a current depending on the RF input signal.

(5)

The output of the multiplier (i_OUT) is the product of these two current and equals:

i_LF²ꢀ i_RF

i_out

I₀

where

•

I₀is a normalizing current.

(6)

By a low-pass filter at the output of the multiplier the DC term of this current is isolated and integrated. The input

of the amplifier A acts as the nulling point of the negative feedback loop, yielding:

i_LF²dt = i_RF²dt

(7)

which implies that the average power content of the current related to the output voltage of the LMH2110 is

made equal to the average power content of the current related to the RF input signal.

For a negative-feedback system, the transfer function is given by the inverse function of the feedback block.

Therefore, to have a logarithmic transfer for this RF detector, the feedback network implements an exponential

function resulting in an overall transfer function for the LMH2110 of:

V_x

V_RF²dt

V_out= V₀log

where

•

V₀and V_Xare normalizing voltages.

(8)

As a result of the feedback loop a square-root is also implemented, yielding the RMS function.

Given this architecture for the RF detector, the high-performance of the LMH2110 can be understood. In theory

the accuracy of the logarithmic transfer is set by:

•

The exponential feedback network, which basically needs to process a DC signal only.

A high loop gain for the feedback loop, which is specified by the amplifier gain A.

The RMS functionality is inherent to the feedback loop and the use of a multiplier; thus, a very accurate LOG-

RMS RF power detector is obtained.

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Feature Description (continued)

To ensure a low dependency on the supply voltage, the internal detector circuitry is supplied via a low drop-out

(LDO) regulator. This enables the usage of a wide range of supply voltage (2.7 V to 5 V) in combination with a

low sensitivity of the output signal for the external supply voltage.

7.3.3.1 RF Input

Refer to Application With Resistive Divider for more details and applications.

7.3.3.2 Enable

To save power, the LMH2110 can be brought into a low-power shutdown mode by means of the enable pin (EN).

The device is active for EN = HIGH (V_EN>1.1 V) and in the low-power shutdown mode for EN = LOW

(V_EN< 0.6 V). In this state the output of the LMH2110 is switched to a high impedance mode. This high

impedance mode prevents the discharge of the optional low-pass filter which is good for the power efficiency.

Using the shutdown function, care must be taken not to exceed the absolute maximum ratings. Because the

device has an internal operating voltage of 2.5 V, the voltage level on the enable must not be higher than 3 V to

prevent damage to the device. Also enable voltage levels lower than 400 mV below GND must be prevented. In

both cases the ESD devices start to conduct when the enable voltage range is exceeded, and excessive current

is drawn. A correct operation is not ensured then. The absolute maximum ratings are also exceeded when the

enable (EN) is switched to HIGH (from shutdown to active mode) while the supply voltage is switched off. This

situation must be prevented at all times. A possible solution to protect the device is to add a resistor of 1 kΩ in

series with the enable input to limit the current.

7.3.3.3 Output

Refer to Application With Low-Pass Output Filter for Residual Ripple Reduction for more details and applications.

7.3.3.4 Supply

The LMH2110 has an internal LDO to handle supply voltages between 2.7 V to 5 V. This enables a direct

connection to the battery in cell-phone applications. The high PSRR of the LMH2110 ensures that the

performance is constant over its power supply range.

7.4 Device Functional Modes

To save power, the LMH2120 has an Enable/Disable feature that can bring the device in low-power shutdown

mode. For implementation details, refer to Enable.

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8 Application 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 must

validate and test their design implementation to confirm system functionality.

8.1 Application Information

The LMH2110 is a 45-dB Logarithmic RMS power detector particularly suited for accurate power measurements

of modulated RF signals that exhibit large peak-to-average ratios (PARs). The RMS detector implements the

exact definition of power resulting in a power measurement insensitive to high PARs. Such signals are

encountered, for exampe, in LTE and W-CDMA applications. The LMH2110 has an RF frequency range from

50 MHz to 8 GHz. It provides an output voltage that relates linearly to the RF input power in dBm. Its output

voltage is highly insensitive to temperature and supply variations.

8.2 Typical Applications

8.2.1 Application With Transmit Power Control

The LMH2110 can be used in a wide variety of applications such as LTE, W-CDMA, CDMA, and GSM. Transmit-

power-control-loop circuits make the transmit power level insensitive to PA inaccuracy. This is desirable because

power amplifiers are non-linear devices and temperature dependent, making it hard to estimate the exact

transmit power level. If a control loop is used, the inaccuracy of the PA is eliminated from the overall accuracy of

the transmit power level. The accuracy of the transmit power level now depends on the RF detector accuracy

instead. The LMH2110 is especially suited for transmit power control applications, because it accurately

measures transmit power and is insensitive to temperature, supply voltage and modulation variations.

Figure 44 shows a simplified schematic of a typical transmit power control system. The output power of the PA is

measured by the LMH2110 through a directional coupler. The measured output voltage of the LMH2110 is

digitized by the ADC inside the baseband chip. Accordingly, the baseband controls the PA output power level by

changing the gain control signal of the RF VGA. Although the output ripple of the LMH2110 is typically low

enough, an optional low-pass filter can be placed in between the LMH2110 and the ADC to further reduce the

ripple.

COUPLER

VGA

GAIN

ADC

ANTENNA

50:

OPTIONAL

OUT

LMH2110

B2, C1

GND

Figure 44. Transmit Power Control System

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Typical Applications (continued)

8.2.1.1 Design Requirements

Some of the design requirements for this logarithmic RMS power detector include:

Table 1. Design Parameters

DESIGN PARAMETER

Supply voltage

EXAMPLE VALUE

2.7 V

1900 MHz

–36 dBm

0 dBm

RF input frequency (unmodulated continuous wave)

Minimum power level

Maximum power level

Maximum output voltage

1.5 V

8.2.1.2 Detailed Design Procedure

8.2.1.2.1 Specifying Detector Performance

The performance of the LMH2110 can be expressed by a variety of parameters.

8.2.1.2.1.1 Dynamic Range

The LMH2110 is designed to have a predictable and accurate response over a certain input power range. This is

called the dynamic range (DR) of a detector. For determining the dynamic range a couple of different criteria can

be used. The most commonly used ones are:

•

Log conformance error, E_LC

Variation over temperature error, E_VOT

1-dB step error, E_{1 dB}

10-dB step error, E_{10 dB}

Variation due to modulation, E_MOD

The specified dynamic range is the range in which the specified error metric is within a predefined window. See

Log Conformance Error, Variation Over Temperature Error, Variation Over Temperature Error, 1-dB Step Error,

10-dB Step Error, and Variation Due to Modulation for an explanation of these errors.

8.2.1.2.1.2 Log Conformance Error

The LMH2110 implements a logarithmic function. In order to describe how close the transfer is to an ideal

logarithmic function the log conformance error is used. To calculate the log conformance error the detector

transfer function is modeled as a linear-in-dB relationship between the input power and the output voltage.

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The ideal linear-in-dB transfer is modeled by 2 parameters:

•

Slope

Intercept

and is described by Equation 9:

V_OUT= K_SLOPE(P_IN– P_INT

)

where

•

K_SLOPEis the slope of the line in mV/dB

P_INthe input power level

P_INTis the power level in dBm at which the line intercepts V_OUT= 0 V (see Figure 45).

(9)

2.4

Ideal

LOG function

2.0

1.6

Detector

response

1.2

0.8

SLOPE

INT

0.4

0.0

-50

-30

-20

-10

RF INPUT POWER (dBm)

Figure 45. Ideal Logarithmic Response

To determine the log conformance error two steps are required:

1. Determine the best fitted line at 25°C.

2. Determine the difference between the actual data and the best fitted line.

The best fit can be determined by standard routines. A careful selection of the fit range is important. The fit range

must be within the normal range of operation of the device. Outcome of the fit is K_SLOPEand P_INT

Subsequently, the difference between the actual data and the best fitted line is determined. The log conformance

is specified as an input referred error. The output referred error is therefore divided by the K_SLOPEto obtain the

input referred error. The log conformance error is calculated by Equation 10:

V_OUTꢀ K_{SLOPE 25qC}(P_INꢀ P_{INT 25qC}

)

E_LC

K_{SLOPE 25qC}

where

•

V_OUTis the measured output voltage at a power level at P_INat a temperature. K_{SLOPE 25°C}(mV/dB).

P_{INT 25°C}(dBm) are the parameters of the best fitted line of the 25°C transfer.

(10)

In Figure 46 both the error with respect to the ideal LOG response as well as the error due to temperature

variation are included in this error metric. This is because the measured data for all temperatures is compared to

the fitted line at 25°C. The measurement result of a typical LMH2110 in Figure 46 shows a dynamic range of

36 dB for E_LC= ±1 dB.

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2.4

2.0

1.6

1.2

0.8

0.4

0.0

-40°C

25°C

-1

-2

-3

85°C

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 46. V_OUTand E_LCvs. RF input Power at 1900 MHz

8.2.1.2.1.3 Variation Over Temperature Error

In contrast to the log conformance error, the variation over temperature error (E_VOT) purely measures the error

due to temperature variation. The measured output voltage at 25°C is subtracted from the output voltage at

another temperature. Subsequently, it is translated into an input referred error by dividing it by K_SLOPEat 25°C.

Variation over temperature is given by Equation 11:

E_VOT= (V_{OUT_TEMP}– V_{OUT 25°C}) / K_{SLOPE 25°C}

(11)

The variation over temperature is shown in Figure 47, where a dynamic range of 41 dB is obtained

(from P_MIN= –36 dBm) for E_VOT= ±0.5 dB.

2.0

1.5

1.0

-40°C

0.5

0.0

-0.5

85°C

-1.0

-1.5

-2.0

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 47. E_VOTvs. RF Input Power at 1900 MHz

8.2.1.2.1.4 1-dB Step Error

This parameter is a measure for the error for a 1-dB power step. According to a 3GPP specification, the error

must be less than ±0.3 dB. Often, this condition is used to define a useful dynamic range of the detector.

The 1-dB step error is calculated in 3 steps:

1. Determine the maximum sensitivity.

2. Determine average sensitivity.

3. Calculate the 1-dB step error.

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First the maximum sensitivity (S_MAX) is calculated per temperature by determining the maximum difference

between two output voltages for a 1-dB step within the power range:

S_MAX= V_{OUT P+1}– V_{OUT P}

(12)

To calculate the 1-dB step error an average sensitivity (S_AVG) is used which is the average of the maximum

sensitivity and an allowed minimum sensitivity (S_MIN). The allowed minimum sensitivity is determined by the

application. In this datasheet S_MIN= 30 mV/dB is used. Subsequently, the average sensitivity can be calculated

by:

S_AVG= (S_MAX+ S_MIN) / 2

(13)

The 1-dB error is than calculated by:

E_{1 dB}= (S_ACTUAL- S_AVG) / S_AVG

where

•

S_ACTUAL(actual sensitivity) is the difference between two output voltages for a 1-dB step at a given power

level.

(14)

Figure 48 shows the typical 1-dB step error at 1900 MHz, where a dynamic range of 38 dB over temperature is

obtained for E_1dB= ±0.3 dB.

2.0

1.5

25°C

1.0

0.5

85°C

0.0

-0.5

-1.0

-1.5

-2.0

-40°C

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 48. 1-dB Step Error vs. RF Input Power at 1900 MHz

8.2.1.2.1.5 10-dB Step Error

This error is defined in a different manner than the 1-dB step error. This parameter shows the input power error

over temperature when a 10-dB power step is made. The 10-dB step at 25°C is taken as a reference.

To determine the 10-dB step error, first the output voltage levels (V1 and V2) for power levels P and P+10 dB” at

the 25°C are determined (Figure 49). Subsequently these 2 output voltages are used to determine the

corresponding power levels at temperature T (P_Tand P_T+ X). The difference between those two power levels

minus 10 results in the 10-dB step error.

25°C response

Temp (T)

response

RF (dBm)

P+10 dB

P +X

Figure 49. Graphical Representation of 10-dB Step Calculations

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Figure 50 shows the typical 10-dB step error at 1900 MHz, where a dynamic range of 30 dB is obtained for

E_10dB= ±1 dB.

2.0

1.5

1.0

85°C

0.5

0.0

-0.5

-40°C

-1.0

-1.5

-2.0

-40 -35 -30 -25 -20 -15 -10 -5

RF INPUT POWER (dBm)

Figure 50. 10 dB Step Error vs. RF Input Power at 1900 MHz

8.2.1.2.1.6 Variation Due to Modulation

The response of an RF detector may vary due to different modulation schemes. How much it varies depends on

the modulation form and the type of detector. Modulation forms with high peak-to-average ratios (PAR) can

cause significant variation, especially with traditional RF detectors. This is because the measurement is not an

actual RMS measurement and is therefore waveform dependent.

To calculate the variation due to modulation (E_MOD), the measurement result for an un-modulated RF carrier is

subtracted from the measurement result of a modulated RF carrier. The calculations are similar to those for

variation over temperature. The variation due to modulation can be calculated by:

E_MOD= (V_{OUT_MOD}– V_{OUT_CW}) / K_SLOPE

where

•

V_{OUT_MOD}is the measured output voltage for an applied power level of a modulated signal.

V_{OUT_CW}is the output voltage as a result of an applied un-modulated signal having the same power level. (15)

Figure 51 shows the variation due to modulation for W-CDMA, where a E_MODof 0.09 dB in obtained for a

dynamic range from –38 dBm to –5 dBm.

1.5

1.0

W-CDMA, REL8

0.5

0.0

W-CDMA, REL6

-0.5

W-CDMA, REL7

-1.0

-1.5

-40

-30

-20

-10

RF INPUT POWER (dBm)

Figure 51. Variation Due to Modulation for W-CDMA

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8.2.1.3 Application Curves

2.4

2.0

2.00

1.75

1.50

1.25

1.00

0.75

0.50

0.25

0.00

5.8 GHz

3.5 GHz

1.9 GHz

900 MHz

50 MHz

RF = 0 dBm

RF = -5 dBm

1.6

1.2

0.8

0.4

0.0

RF = -10 dBm

RF = -15 dBm

RF = -20 dBm

RF = -25 dBm

8 GHz

-40

-30

-20

-10

10M

100M

10G

RF INPUT POWER (dBm)

FREQUENCY (Hz)

Figure 52. Output Voltage vs. RF Input Power

Figure 53. Output Voltage vs. Frequency

8.2.2 Application With Resistive Divider

RF systems typically use a characteristic impedance of 50 Ω. The LMH2110 is no exception to this. The RF input

pin of the LMH2110 has an input impedance of 50 Ω. It enables an easy, direct connection to a directional

coupler without the need for additional components (Figure 44). For an accurate power measurement the input

power range of the LMH2110 needs to be aligned with the output power range of the power amplifier. This can

be done by selecting a directional coupler with the correct coupling factor.

Because the LMH2110 has a constant input impedance, a resistive divider can also be used instead of a

directional coupler (Figure 54).

ANTENNA

OUT

LMH2110

ADC

B2, C1

GND

Figure 54. Application With Resistive Divider

Resistor R₁implements an attenuator together with the detector input impedance to match the output range of

the PA to the input range of the LMH2110. The attenuation (A_dB) realized by R₁and the effective input

impedance of the LMH2110 equals:

R_{1 º}

A_dB= 20LOG 1 +

R_IN

(16)

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Solving Equation 16 for R₁yields:

R₁=

- 1 R_IN

(17)

Suppose the desired attenuation is 30 dB with a given LMH2110 input impedance of 50 Ω, the resistor R₁needs

to be 1531 Ω. A practical value is 1.5 kΩ. Although this is a cheaper solution than the application with directional

coupler, it also comes with a disadvantage. After calculating the resistor value it is possible that the realized

attenuation is less then expected. This is because of the parasitic capacitance of resistor R₁which results in a

lower actual realized attenuation. Whether the attenuation is reduced depends on the frequency of the RF signal

and the parasitic capacitance of resistor R₁. Because the parasitic capacitance varies from resistor to resistor,

exact determination of the realized attenuation can be difficult. A way to reduce the parasitic capacitance of

resistor R₁is to realize it as a series connection of several separate resistors.

8.2.3 Application With Low-Pass Output Filter for Residual Ripple Reduction

The output of the LMH2110 provides a DC voltage that is a measure for the applied RF power to the input pin.

The output voltage has a linear-in-dB response for an applied RF signal.

RF power detectors can have some residual ripple on the output due to the modulation of the applied RF signal.

The residual ripple on the output of the LMH2110 device is small though and, therefore, additional filtering is

usually not needed. This is because its internal averaging mechanism reduces the ripple significantly. For some

modulation types however, having very high peak-to-average ratios, additional filtering might be useful.

Filtering can be applied by an external low-pass filter. Filtering reduces not only the ripple, but also increases the

response time. In other words, it takes longer before the output reaches its final value. A trade-off must be made

between allowed ripple and allowed response time. The filtering technique is depicted in Figure 55. The filtering

of the low pass output filter is realized by resistor R_Sand capacitor C_S. The –3-dB bandwidth of this filter can be

calculated by:

f_{−3 dB}= 1 / (2πR_SC_S)

(18)

OUT

LMH2110

ADC

B2,C1

GND

Figure 55. Low-Pass Output Filter for Residual Ripple Reduction

The output impedance of the LMH2110 is HIGH in shutdown. This is especially beneficial in pulsed mode

systems. It ensures a fast settling time when the device returns from shutdown into active mode and reduces

power consumption.

In pulse mode systems, the device is active only during a fraction of the time. During the remaining time the

device is in low-power shutdown. Pulsed mode system applications usually require that the output value is

available at all times. This can be realized by a capacitor connected between the output and GND that “stores”

the output voltage level. To apply this principle, capacitor discharging must be minimized in shutdown mode. The

connected ADC input must therefore have a high input impedance to prevent a possible discharge path through

the ADC. When an additional filter is applied at the output, the capacitor of the RC-filter can be used to store the

output value. An LMH2110 with a high impedance shutdown mode saves power in pulse mode systems. This is

because the capacitor C_Sdoes not need to be fully re-charged each cycle.

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9 Power Supply Recommendations

The LMH2110 is designed to operate from an input voltage supply range between 2.7 V to 5 V. This input

voltage must be well regulated. Enable voltage levels lower than 400 mV below GND could lead to incorrect

operation of the device. Also, the resistance of the input supply rail must be low enough to ensure correct

operation of the device.

10 Layout

10.1 Layout Guidelines

As with any other RF device, pay close careful attention to the board layout. If the board layout is not properly

designed, performance might be less then can be expected for the application.

The LMH2110 is designed to be used in RF applications, having a characteristic impedance of 50 Ω. To achieve

this impedance, the input of the LMH2110 needs to be connected via a 50-Ω transmission line. Transmission

lines can be created on PCBs using microstrip or (grounded) coplanar waveguide (GCPW) configurations.

In order to minimize injection of RF interference into the LMH2110 through the supply lines, the PCB traces for

VDD and GND must be minimized for RF signals. This can be done by placing a small decoupling capacitor

between the VDD and GND. It must be placed as close as possible to the VDD and GND pins of the LMH2110.

10.2 Layout Example

Figure 56. LMH2110 Layout

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11 Device and Documentation Support

11.1 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.

11.2 Trademarks

E2E is a trademark of Texas Instruments.

All other trademarks are the property of their respective owners.

11.3 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.

11.4 Glossary

SLYZ022 — TI Glossary.

This glossary lists and explains terms, acronyms, and definitions.

12 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.

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PACKAGE OPTION ADDENDUM

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10-Dec-2020

PACKAGING INFORMATION

Orderable Device

Status Package Type Package Pins Package

Eco Plan

Lead finish/

Ball material

MSL Peak Temp

Op Temp (°C)

Device Marking

Samples

Drawing

Qty

(1)

(2)

(3)

(4/5)

(6)

LMH2110TM/NOPB

LMH2110TMX/NOPB

ACTIVE

DSBGA

YFQ

250

RoHS & Green

SNAGCU

Level-1-260C-UNLIM

-40 to 85

3000 RoHS & Green

SNAGCU

⁽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⁾RoHS: TI defines "RoHS" to mean semiconductor products that are compliant with the current EU RoHS requirements for all 10 RoHS substances, including the requirement that RoHS substance

do not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, "RoHS" products are suitable for use in specified lead-free processes. TI may

reference these types of products as "Pb-Free".

RoHS Exempt: TI defines "RoHS Exempt" to mean products that contain lead but are compliant with EU RoHS pursuant to a specific EU RoHS exemption.

Green: TI defines "Green" to mean the content of Chlorine (Cl) and Bromine (Br) based flame retardants meet JS709B low halogen requirements of <=1000ppm threshold. Antimony trioxide based

flame retardants must also meet the <=1000ppm threshold requirement.

⁽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 finish/Ball material - Orderable Devices may have multiple material finish options. Finish options are separated by a vertical ruled line. Lead finish/Ball material values may wrap to two

lines if the finish value exceeds the maximum column width.

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.

Addendum-Page 1

PACKAGE OPTION ADDENDUM

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10-Dec-2020

Addendum-Page 2

PACKAGE MATERIALS INFORMATION

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5-Nov-2022

TAPE AND REEL INFORMATION

REEL DIMENSIONS

TAPE DIMENSIONS

Reel

Diameter

Cavity

A0 Dimension designed to accommodate the component width

B0 Dimension designed to accommodate the component length

K0 Dimension designed to accommodate the component thickness

Overall width of the carrier tape

P1 Pitch between successive cavity centers

Reel Width (W1)

QUADRANT ASSIGNMENTS FOR PIN 1 ORIENTATION IN TAPE

Sprocket Holes

Q1 Q2

Q3 Q4

Q1 Q2

Q3 Q4

User Direction of Feed

Pocket Quadrants

*All dimensions are nominal

Device

Package Package Pins

Type Drawing

SPQ

Reel

Pin1

Diameter Width (mm) (mm) (mm) (mm) (mm) Quadrant

(mm) W1 (mm)

LMH2110TM/NOPB

LMH2110TMX/NOPB

DSBGA

YFQ

250

178.0

8.4

1.04

1.4

0.76

4.0

8.0

3000

Pack Materials-Page 1

PACKAGE MATERIALS INFORMATION

www.ti.com

5-Nov-2022

TAPE AND REEL BOX DIMENSIONS

Width (mm)

*All dimensions are nominal

Device

Package Type Package Drawing Pins

SPQ

Length (mm) Width (mm) Height (mm)

LMH2110TM/NOPB

LMH2110TMX/NOPB

DSBGA

YFQ

250

208.0

191.0

35.0

3000

Pack Materials-Page 2

MECHANICAL DATA

YFQ0006xxx

0.600±0.075

TMD06XXX (Rev B)

D: Max = 1.27 mm, Min = 1.21 mm

E: Max = 0.87 mm, Min = 0.81 mm

4215075/A

12/12

A. All linear dimensions are in millimeters. Dimensioning and tolerancing per ASME Y14.5M-1994.

B. This drawing is subject to change without notice.

NOTES:

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LMH2110TM/NOPB [TI]

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