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LT2940

Power and Current Monitor

FEATURES

DESCRIPTION

The LT

2940 measures a high side current and a differ-

ential voltage, multiplies them and outputs a current

proportional to instantaneous power. Bidirectional high

side currents and bipolar voltage differences are correctly

handled by the four-quadrant multiplier and push-pull

output stage, which allows the LT2940 to indicate forward

and reverse power ﬂow.

An integrated comparator with inverting and noninvert-

ing open-collector outputs makes the LT2940 a complete

power level monitor. In addition, an output current pro-

portional to the sensed high side current allows current

monitoring. The current mode outputs make scaling,

ﬁltering and time integration as simple as selecting ex-

ternal resistors and/or capacitors.

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.

Four-Quadrant Power Measurement

±5% Power Measurement Accuracy

4V to 80V High Side Sense, 100V Max

Current Mode Power and Current Outputs

Output Bandwidth Exceeds 500kHz

±3% Current Measurement Accuracy

6V to 80V Supply Range, 100V Max

Inverting and Noninverting Open-Collector

Comparator Outputs

Available in 12-Pin DFN (3mm

3mm) and 12-Lead

MSOP Packages

APPLICATIONS

Board Level Power and Current Monitoring

Line Card and Server Power Monitoring

Power Sense Circuit Breaker

Power Control Loops

Power/Energy Meters

Battery Charger Metering

TYPICAL APPLICATION

Load Monitor Alarms Above 60W

LOAD

6V TO 80V

20mΩ

LATCH

CMPOUT

LED ON WHEN

LOAD

> 60W

CMPOUT

CMP

PMON

= P

LOAD

• 20.75 mV

24.9K

= 1

= 20mΩ

LOAD

= V

LOAD

• I

LOAD

2940 TA01a

Monitor Output Level and Load Power

2.5

LOAD

–

PMON

(V)

80V

30V

2.0

15V

10V

1.5

LOAD

= 6V

LOAD

(W)

120

0A TO 10A

LOAD

–

110k

LED ON

LT2940

10.0k

–

1.0

LED OFF 48

60W ALARM

0.5

GND

IMON

= I

LOAD

• 100

4.99k

LOAD

(A)

2940 TA01b

2940f

LT2940

ABSOLUTE MAXIMUM RATINGS

(Notes 1, 2)

, I

–

, LATCH .................................... –0.3V to 100V

, V

–

, CMP

............................................. –0.3V to 36V

Voltage Sense (V

– V

–

) .........................................±36V

Current Sense (I

– I

–

) ............................................±36V

PMON, IMON (Note 3) ...... –0.3V to V

+ 1V, Up to 16V

CMPOUT,

CMPOUT

.................................... –0.3V to 36V

CMPOUT,

CMPOUT

DC Output Current ..................22mA

Operating Temperature Range

LT2940C................................................... 0°C to 70°C

LT2940I ................................................–40°C to 85°C

Storage Temperature Range...................–65°C to 150°C

Lead Temperature (Soldering, 10 sec)

MSOP Package ................................................. 300°C

PIN CONFIGURATION

TOP VIEW

CMPOUT

CMP

PMON

IMON

GND

TOP VIEW

12 V

11 I

10 I

–

9 LATCH

8 V

7 V

–

CMPOUT

CMP

PMON

IMON

GND

–

LATCH

–

DD PACKAGE

12-LEAD (3mm 3mm) PLASTIC DFN

JMAX

= 125°C,

= 43°C/W

EXPOSED PAD (PIN 13) PCB GND CONNECTION OPTIONAL

MS PACKAGE

12-LEAD PLASTIC MSOP

JMAX

= 125°C,

= 135°C/W

ORDER INFORMATION

LEAD FREE FINISH

LT2940CDD#PBF

LT2940IDD#PBF

LT2940CMS#PBF

LT2940IMS#PBF

TAPE AND REEL

LT2940CDD#TRPBF

LT2940IDD#TRPBF

LT2940CMS#TRPBF

LT2940IMS#TRPBF

PART MARKING*

LDPP

2940

PACKAGE DESCRIPTION

12-Lead Plastic DFN

12-Lead Plastic MSOP

TEMPERATURE RANGE

0°C to 70°C

–40°C to 85°C

0°C to 70°C

–40°C to 85°C

Consult LTC Marketing for parts speciﬁed with wider operating temperature ranges. *The temperature grade is identiﬁed by a label on the shipping container.

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/

2940f

LT2940

ELECTRICAL CHARACTERISTICS

SYMBOL

Supply

CC(UVLC)

ΔV

CC(HYST)

Voltage Sense

VSEN(OR)

Voltage Sense Pin Operating Range

Pin and V

–

≤ 12V

12V < V

< 30V

≥ 30V

Voltage Sense Differential Input Voltage Range V

< 11V

(Note 5)

= V

– V

–

V(CL)

VSEN

ΔI

VSEN

Current Sense

ISEN(OR)

Current Sense Pin Operating Range

Pin and I

–

Current Sense Differential Input Voltage

Range (Note 6)

= V

– V

–

Current Sense Differential Clipping Limit

(Note 6)

Current Sense Input Bias Current

Pin and I

–

Current Sense Input Offset Current

ΔI

ISEN

= I

– I

–

Power Monitor Output Current Operating

Range

Power Monitor Output Current Capability

≥ 12V, V

PMON

≥ 0V, and

= –9V, V

= –225mV, or

= 9V, V

= 225mV

≥ 12V, V

PMON

≥ 0.5V, and

= –9V, V

= 225mV, or

= 9V, V

= –225mV

≥ 12V, V

PMON

≥ 4V, and

= –9V, V

= 225mV, or

= 9V, V

= –225mV

= V

–

The

denotes the speciﬁcations which apply over the full operating

temperature range, otherwise speciﬁcations are at T

= 25°C. All speciﬁcations apply at 6V ≤ V

≤ 80V, unless otherwise speciﬁed.

PARAMETER

Supply Voltage Operating Range

Supply Current

Supply Undervoltage Latch Clear

Supply Undervoltage Hysteresis

PMON

= +200μA, I

IMON

= +200μA

(Note 2)

Falling

Rising

CONDITIONS

MIN

2.3

–0.1

±(V

– 3)

±8

±9

–300

TYP

MAX

UNITS

3.5

2.5

2.7

100

– 3

≥ 11V

≥ 12V

Voltage Sense Differential Clipping Limit

(Note 5)

Voltage Sense Input Bias Current

Pin and V

–

Voltage Sense Input Offset Current

ΔI

VSEN

= I

– I

–

–100

±50

100

±150

= V

–

±200

I(CL)

ISEN

ΔI

ISEN

±225

100

±200

125

±800

μA

Power Monitor (Note 2)

PMON(OR)

PMON(CAPA)

±200

900

1200

μA

–240

–1200

μA

–800

–1200

μA

2940f

LT2940

ELECTRICAL CHARACTERISTICS

SYMBOL

PMON

PARAMETER

Power Monitor Output Compliance Voltage

The

denotes the speciﬁcations which apply over the full operating

temperature range, otherwise speciﬁcations are at T

= 25°C. All speciﬁcations apply at 6V ≤ V

≤ 80V, unless otherwise speciﬁed.

CONDITIONS

≤ 12V, I

PMON

≥ 0μA

12V < V

< 30V, I

PMON

≥ 0μA

≥ 30V, I

PMON

≥ 0μA

≤ 12V, I

PMON

< 0μA

12V < V

< 30V, I

PMON

< 0μA

≥ 30V, I

PMON

< 0μA

MIN

0.5

TYP

MAX

– 4.5

7.5

– 4.5

7.5

UNITS

%FS

μA /V

μA

MHz

μA

PMON

Power Monitor Output Total Error (Note 4)

• V

| ≤ 0.4V

• V

| ≤ 0.4V

, 25°C < T

≤ 85°C

• V

| ≤ 0.4V

, LT2940C

• V

| ≤ 0.4V

, LT2940I

Quadrants I and III of Shaded Region

in Figure 4

±2

±2.5

±3.5

±5

485

500

±40

±2

±6

0.5

±5

±7

±9

±12

±15

515

±100

±6

±15

PMON

V(OSP)

I(OSP)

PMON(OS)

PMON

IMON(FS)

IMON

Power Monitor Scaling Coefﬁcient

PMON

= K

PMON

• V

Power Monitor Voltage Sense Input-Referred

Offset Voltage

Power Monitor Current Sense Input-Referred

Offset Voltage

Power Monitor Output Offset Current

Power Monitor Output Bandwidth

Current Monitor Output Current Operating

Range

Current Monitor Output Compliance Voltage

• V

| = 0.4V

= 0V

= 0mV

–

= 0V, V

= 0mV

PMON

= 2k

Current Monitor (Note 2)

±200

0.5

±1.5

≤ 12V, I

IMON

≥ 0μA

12V < V

< 30V, I

IMON

≥ 0μA

≥ 30V, I

IMON

≥ 0μA

≤ 12V, I

IMON

< 0μA

12V < V

< 30V, I

PMON

< 0μA

≥ 30V, I

PMON

< 0μA

– 4.5

7.5

– 4.5

7.5

±3

±3.5

±4

±5

1025

±7

±2

±2.5

%FS

μA /V

MHz

IMON

Current Monitor Output Total Error (Note 4)

| ≤ 200mV, 25°C ≤ T

≤ 85°C

| ≤ 200mV, LT2940C

| ≤ 200mV, LT2940I

200mV < |V

| ≤ 225mV

IMON

I(OSI)

IMON

Comparator

CMP(TH)

ΔV

CMP(HYST)

CMP(BIAS)

CMPOUT(OL)

Current Monitor Scaling, I

IMON

= G

IMON

• V

Current Monitor Current Sense Input-Referred

Offset Voltage

Current Monitor Output Bandwidth

Comparator Threshold Voltage

Comparator Threshold Hysteresis

Comparator Input Bias Current

CMPOUT Output Low Voltage

= ±200mV

975

1000

±2.5

IMON

= 2k

CMP

Rising

CMP

Falling

1V ≤ V

CMP+

≤ 1.5V

CMP

High, I

CMPOUT

= 3mA

1.222

–15

1.240

–35

±100

0.2

1.258

–60

±300

0.4

2940f

LT2940

ELECTRICAL CHARACTERISTICS

SYMBOL

CMPOUT(LK)

CMPOUT(OL)

CMPOUT(LK)

DLY

LATCH(IL)

LATCH(IO)

LATCH(IH)

LATCH(LK)

LATCH(BIAS)

PARAMETER

CMPOUT Leakage Current

CMPOUT

Output Low Voltage

CMPOUT

Leakage Current

Comparator Propagation Delay

LATCH Input Low Voltage

LATCH Input Open Voltage

LATCH Input High Voltage

LATCH Input Allowable Leakage in

Open State

LATCH Input Bias Current

LATCH

= 0V

LATCH

= 80V

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:

All currents into pins are positive, and all voltages are referenced

to GND unless otherwise noted. Current sourced by the PMON pin or the

IMON pin is deﬁned as positive; current sunk as negative.

The

denotes the speciﬁcations which apply over the full operating

temperature range, otherwise speciﬁcations are at T

= 25°C. All speciﬁcations apply at 6V ≤ V

≤ 80V, unless otherwise speciﬁed.

CONDITIONS

CMP

Low, V

= 36V,

0.4V ≤ V

CMPOUT

≤ 36V

CMP

Low, I

CMPOUT

= 3mA

CMP

High, V

= 36V,

0.4V ≤ V

CMPOUT

≤ 36V

Output Pulling Down

MIN

TYP

±0.15

0.2

±0.15

0.7

MAX

±1

0.4

±1

1.2

1.95

2.5

±10

UNITS

μA

μs

μA

0.5

1.25

2.0

0.8

1.5

2.2

–11

–17

–23

Note 3:

The LT2940 may safely drive its own PMON and IMON output

voltages above the absolute maximum ratings. Do not apply any external

source that drives the voltage above absolute maximum.

Note 4:

Full-scale equals ±200μA.

Note 5:

and V

–

pin voltages must each fall within the voltage sense pin

operating range speciﬁcation.

Note 6:

and I

–

pin voltages must each fall within the current sense pin

operating range speciﬁcation.

TYPICAL PERFORMANCE CHARACTERISTICS

PMON Output Current

vs Sense Input Voltages

800

600

PMON

(%FS)

400 –4V

PMON

(μA)

200 –2V

–200

–400

–200

(mV)

200

2940 G01

PMON Total Error

vs Sense Input Voltages

ONE REPRESENTATIVE UNIT

–2V

–1

–2

–3

–200

= 8V

• V

| ≤ 0.4V

= 25°C

–100

(mV)

2940 G02

PMON Error Band vs Temperature

= V

V+

– V

V –

= V

I+

– V

I –

= –8V

≥ 11V

PMON

= 0.5V

–4V

= 8V

PMON

(%FS)

–1

–2

–3

–4

–50

–8V ≤ V

≤ 8V

–200mV ≤ V

≤ 200mV

• V

| ≤ 0.4V

= 80V

= 12V

= 80V

–25

TEMPERATURE (°C)

100

125

100

200

2949 G03

2940f

型号	LT2940IDD#PBF	LT2940CDD#PBF	LT2940CDD#TRPBF	LT2940CMS#PBF	LT2940CMS#TRPBF	LT2940IDD#TRPBF	LT2940IMS#PBF	LT2940IMS#TRPBF
描述	Monitor 6V to 80V Automotive 12-Pin DFN EP Tube	Monitor 6V to 80V Automotive 12-Pin DFN EP Tube	Monitor 6V to 80V Automotive 12-Pin DFN EP T/R	Monitor 6V to 80V Automotive 12-Pin MSOP Tube	Monitor 6V to 80V Automotive 12-Pin MSOP T/R	Monitor 6V to 80V Automotive 12-Pin DFN EP T/R	Monitor 6V to 80V Automotive 12-Pin MSOP Tube	Monitor 6V to 80V Automotive 12-Pin MSOP T/R
欧盟限制某些有害物质的使用	Compliant	Compliant	Compliant	Compliant	Compliant	Compliant	Compliant	Compliant
ECCN (US)	EAR99	EAR99	EAR99	EAR99	EAR99	EAR99	EAR99	EAR99
Part Status	Active	Active	Active	Active	Active	Active	Active	Active
类型 Type	Monitor	Monitor	Monitor	Monitor	Monitor	Monitor	Monitor	Monitor
Input Voltage (V)	6 to 80	6 to 80	6 to 80	6 to 80	6 to 80	6 to 80	6 to 80	6 to 80
Output Current (A)	0.022(Max)	0.022(Max)	0.022(Max)	0.022(Max)	0.022(Max)	0.022(Max)	0.022(Max)	0.022(Max)
Minimum Operating Supply Voltage (V)	6	6	6	6	6	6	6	6
Maximum Operating Supply Voltage (V)	80	80	80	80	80	80	80	80
Maximum Supply Current (mA)	5	5	5	5	5	5	5	5
Maximum Operating Temperature (°C)	85	70	70	70	70	85	85	85
Supplier Temperature Grade	Industrial	Commercial	Commercial	Commercial	Commercial	Industrial	Industrial	Industrial
系列 Packaging	Tube	Tube	Tape and Reel	Tube	Tape and Reel	Tape and Reel	Tube	Tape and Reel
Standard Package Name	DFN	DFN	DFN	MSOP	MSOP	DFN	MSOP	SOP
Pin Count	12	12	12	12	12	12	12	12
Supplier Package	DFN EP	DFN EP	DFN EP	MSOP	MSOP	DFN EP	MSOP	MSOP
Mounting	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount	Surface Mount
Package Height	0.75(Max)	0.75(Max)	0.75(Max)	0.86	0.86	0.75(Max)	0.86	0.86
Package Length	3	3	3	4.04	4.04	3	4.04	4.04
Package Width	3	3	3	3	3	3	3	3
PCB changed	12	12	12	12	12	12	12	12
Lead Shape	No Lead	No Lead	No Lead	Gull-wing	Gull-wing	No Lead	Gull-wing	Gull-wing
HTS	8542.39.00.01	8542.39.00.01	8542.39.00.01	-	8542.39.00.01	8542.39.00.01	-	8542.39.00.01

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传小米下月申请香港上市或成首批同股不同权企业

据港媒报道，市场消息透露，小米或于下月在港申请上市，于下月“同股不股权”新例生效后立即入表，最快于6月至7月期间上市，为首批在港上市的同股不同权企业。消息指，小米已委聘高盛、摩根士丹利及中信证券为保荐人，安排上市事宜，初步料集资额约780亿元，其后或扩大承销团队。消息又指，在公布同股不同权咨询前，港交所已游说小米来港上市，担心若首轮上市企业名气或实力不足，影响市场信心，故冀小米能成为首批上市...[详细]
苹果中国官网上线iOS 18介绍页面：全程未提AI

7月4日消息，苹果中国官网最新上线了iOS 18介绍页面，详细展示了iOS 18的新设计和新功能。值得注意的是，页面中全程没有提及iOS 18的最大亮点——AI。苹果在今年WWDC上着重介绍了各种AI功能，并且发布了自家大模型Apple Intelligence，同时还与ChatGPT进行了合作，系统直接调用ChatGPT的能力。然而，不论是ChatGPT还是Apple Intellige...[详细]
三星Galaxy S10更新后无法使用只能强制恢复出厂

系统更新的意义就在于可以对已知Bug进行修复，在系统稳定性得到进一步提升的同时为消费者带来全新的使用体验。不过系统更新似乎也不都是好的，比如以“慢”及“用户小白鼠”著称的三星系统更新。最近在三星的官方论坛上出现了不少用户求助信息，有许多用户反映称Galaxy S10和S10 Plus在安装了新的OTA系统更新后变砖，无法正常使用手机。具体情况是在开机之后会要求用户输入PIN码（没有输入框）...[详细]
又到一年梅雨季，是时候放飞系留无人机了！

一到6、7月份，高温不断、黏湿不堪、降水不止的“梅雨季”便如期而至。据国家气候中心监测，6月1日我国江南地区已经正式入梅，比往年还提早了近一周。截至目前，江西、浙江、广东等地降水明显增强，短时强降水、雷雨大风等天气多发。在此天气下，虽说短期内会让我们暂别酷热的炎夏，获得一丝清凉，但久而久之也容易滋生一些次生灾害和问题，比如城市内涝、中小河流洪水以及山洪地质灾害。据悉，当前浙江已有80多个地区发...[详细]
特斯拉发布Autopilot最新安全报告

1月15日，特斯拉发布了2021年第四季度Autopilot自动驾驶技术安全报告。尽管数据有限，难以进行全面的安全分析，但报告仍显示出特斯拉Autopilot在安全方面取得的进步。自2018年以来，特斯拉通过发布季度安全报告，比较了在Autopilot自动驾驶模式下和非Autopilot自动驾驶模式下的事故率，以为其在改进自动驾驶安全方面创造一个基准。而最新的第四季度报告显示，在Au...[详细]
s3c2440裸机-电阻触摸屏编程(2.触摸屏TS控制器)

触摸屏接口模式 Normal Conversion Mode: 正常转换模式，一般情况下可以配置ADCCON和ADCDAT0来读取数据。 Separate X/Y position conversion Mode： x,y坐标分离转换格式，x坐标会写入ADCDAT0, y坐标会写入ADCDAT1,所以会产生2次中断开分开完成x,y的坐标转换。 Auto(Sequential) X/...[详细]
深入解析汽车MCU的软件架构

电动汽车（EV）正在成为首选的交通方式，为传统内燃机汽车提供了一种可持续发展的环保型替代方案。在电动汽车复杂的生态系统中，众多电子控制单元（ECU）在确保其高效运行方面发挥着至关重要的作用。电机控制单元（MCU）就是这样一个 ECU，它是电机性能背后的大脑。在这篇综合文章中，我们将探索电机控制单元的世界，研究它们的功能、组件以及影响汽车 MCU 领域的最新趋势。了解电动汽车使用的电机在深...[详细]