DC2156A留学生代做、Python，c++，Java程序设计代写、代做system monitor

日期：2019-03-02 09:56

DEMO MANUAL DC2156A

Description

LTC2946

Wide Range I2C Power,

Charge and Energy Meter

Demonstration circuit 2156A features the LTC 2946

rail-to-rail system monitor that measures current, voltage,

power, energy and charge. It features an operating

range of 2.7V to 100V and includes a shunt regulator for

operation from supplies above 100V to allow flexibility in

the selection of input supply. The current measurement

range of 0V to 100V is independent of the input supply.

An onboard, 0.4% accurate, 12-bit ADC measures load

current, input voltage and an auxiliary external voltage.

A 24-bit power value is generated by digitally multiplying

the measured 12-bit load current and input voltage data.

Energy andchargedata aregeneratedby integratingpower

and current. Minimum and maximum values are stored

and an overrange alert with programmable thresholds

minimizes the need for software polling. Data is reported

via a standard I2C interface. Shutdown mode reduces

power consumption to 20μA.

L, LT, LTC, LTM, Linear Technology and the Linear logo are registered trademarks and

QuikEval and Linduino are trademarks of Linear Technology Corporation. All other trademarks

are the property of their respective owners.

The demo board features nested pads for a range of sense

resistor package sizes to support currents of up to 15A

range. The full scale sense voltage is 102.4mV. A 20mΩ

sense resistor is populated on the board for 5.12A full

scale. The full scale current can be changed by populating

RSNS accordingly.

The DC2156A was designed to be connected to the DC590

andcontrolledthroughtheQuikEval? suiteof software. All

thresholds can be set and ADC registers read back through

the QuikEval interface, which provides a convenient way

to evaluate the LTC2946.

Figure 1. Typical Application Circuit

DEMO MANUAL DC2156A

DC2156A Pin and Jumper Definitions

Jumper Settings

JP1: Selects the VDD source. It can be set to VIN, INTVCC

or EXTVDD (which requires a voltage to be present at the

EXTVDD turret.) Please see Powering the DC2156A section

for examples of how these different settings are used.

JP2 (ADR0), JP3(ADR1): Selects the I2C slave address

of the LTC2946. Any changes here should also be made

inside of QuikEval for communications to persist. By

default, both jumpers are set to LOW which corresponds

to an address of 0xDE.

Turrets and Banana Jacks

Signal connections are made via the row of turret posts

along the edges of the board.

GND: (5 turrets, 2 banana jacks) These turrets are connected

directly to the ground planes.

VIN: Main Supply Input. The LTC2946 measures the current

flowing from VIN to VOUT.

VOUT: Supply Output to Load. The LTC2946 measures the

current flowing from VIN to VOUT.

INTVCC: Internal Low Voltage Supply Input/Output. This

turret is directly connected to the INTVCC pin. This turret is

used to power internal circuitry and can be configured as

a direct input, as a linear regulator from a higher voltage

connected to VDD or as a shunt regulator. In the default

configurationwithJP1 at VIN, INTVCCisinternallygenerated

and is 5V. Please see LTC2946 data sheet for more details.

EXTVDD: External Voltage Supply. This turret can be used

to power the LTC2946 independently of the VIN power

path. Connect to 4V to 100V external supply if this option

is selected through JP1.

ADIN: Input Measured by the Onboard ADC. Measures

between 0V to 2.048V. ADIN is loaded with a 140k and

3k resistive divider to allow voltage measurements of up

to 102.4V full scale.

VPU: Pull Up Voltage for the LEDs. Derived from a 5V

isolated supply on the DC590. It powers the GPIO LEDs

on the board. If a DC590 is not used and the DC2156A

is operated independently, a 2.5V to 5V supply must be

provided here, in order for the LEDs to work. 5V from

DC590 and the VPU turret input voltage are diode-ORed by

D6 to preclude back feeding from one source to the other.

SENSE+: Supply Voltage and Current Sense Input. Used

as a Kelvin input for the internal current sense amplifier.

The voltage at this pin is also monitored by the onboard

ADC with a full-scale input range of 102.4V. The full scale

current sense voltage is 102.4mV.

SENSE–: Current Sense Input. An external 20mΩ sense

resistor (RSNS) isconnectedbetweenSENSE+andSENSE–

to measure a full scale current of 5.12A. See Hardware

Setup section for details.

SCL: I2C Clock input.

SDA/SDAI: I2C Data Input. Connected to SDAO through

0Ω resistor R14. Remove R14 if opto-isolated I2C functionality

is desired.

SDAO: I2C Data Output. Connected to SDAI through 0Ω

resistor R14. Remove R14 if opto-isolated I2C functionality

is desired.

GPIO1: General Purpose Input/Output 1. Configurable

general purpose output and logic input. Configured by

default as General Purpose Output, pulls low to light D3.

GPIO2: General Purpose Input/Output 2. Configurable

general purpose output, logic input, and ACC control input

to gate internal accumulators. By default it is configured as

ACC input and pulled high so that the energy and charge

accumulation are active. If GPIO2 is configured as an

output, LED D4 lights up when GPIO2 is asserted low.

GPIO3: General Purpose Input/Output 3. Configurable

general purpose output, logic input, and ALERT# output.

By default it is configured as ALERT#. As ALERT#, it is

pulled to ground when a fault occurs to alert the host

controller. LED D5 lights when ALERT# is asserted low.

3

dc2156af

DEMO MANUAL DC2156A

Hardware Setup Options

Flexible Operating Modes of the LTC2946

The LTC2946 current sense inputs, SENSE+ and SENSE–

are used to make Kelvin connections to a current sense

resistor to measure the output current of a supply or the

current consumption of a load. They feature a common

mode range of 0V to 100V so that the output current of

either a positive or negative supply can be measured, as

well as current in either the positive or negative lead of the

load. Thus a potentially bewildering number of measurement

configurations are possible. To allow such flexibility,

the SENSE+ and SENSE– pins cannot be relied upon as

a source of power; the LTC2946 features a separate VDD

pin for this purpose.

Power to operate LTC2946 is obtained from the VDD pin

or the INTVCC pin (see the block diagram in Figure 2). If

a supply of 4V to 100V is available, VDD can be used and

an internal series regulator powers the device. If a supply

of 2.7V to 5.9V is available, power may be applied directly

to INTVCC. In the event that no supply of less than 100V

is available, the shunt regulator shown connected across

INTVCC can be used in conjunction with an external dropping

resistor to power the LTC2946.

Ringing

It comes as a surprise to many that seemingly innocent

acts, such as making a connection to a live supply, cause

ringing. Theory tells us that the amplitude of such ringing

reaches approximately 2x the input voltage, but in practice

this limit is sometimes exceeded. For general information

on ringing, see the LTC1647 data sheet.

Since the VDD pin current is small, ringing there is easily

suppressed by a 51Ω/100nF RC filter (R1 and C1) without

any compromise to the input voltage range. The SENSE+

and SENSE– pins however are not so easily protected.

To protect these pins and to prevent damage to the

LTC2946 that might arise from ringing, VIN is clamped by

an SMAT70A TVS (D1). D1 has a minimum breakdown

voltage of 77V at room temperature and thus VIN DC

input rating to 75V maximum. While D1 may be removed

to operate VIN up to 100V, always remember that any

excursion above this value may destroy the LTC2946.

DC2156A Pin and Jumper Definitions

Connectors

DC590 Connector (J5): J5 allows connection of the

DC2156A to the DC590 demo board through which the

Linear Technology? QuikEval software can communicate

with the board. When DC590 is connected, 5V is provided

to power the GPIO LEDs through this connector.

LED

INTVCC – D2:LightsupgreenwhenbothVPUandLTC2946

are powered.

ALERT# (GPIO3) – D5: Fault Alert Output. Lights up red

on an ALERT condition. Can also be monitored on the

ALERT (GPIO3) turret.

ACC (GPIO2) – D4:Will light up amberwhenACCis Low. By

DefaultGPIO2 is an input, pulled high to VPUby D4 and R7.

GPIO1 – D3: General Purpose Output. Lights up green

when pulled low. Default state is low.

Figure 2. Simplified Supply Block Diagram

VDD

INTVCC

GND

735k

15k

5V LDO LTC2946

SENSE– SENSE+

4

dc2156af

DEMO MANUAL DC2156A

Hardware Setup Options

Powering The DC2156A

The LTC2946 offers great flexibility in terms of supply

options owing to its separate VDD and SENSE pins.

Jumper JP1 is used to select the source of power for VDD

andallowseasyconfigurationofthevarioussupplyoptions.

If JP1 is set to VIN, then VDD is powered from VIN (Figure?3a

and Figure?3b). In this configuration, sensing is done on

the same rail which is supplying power to the LTC2946.

Provide 4V to 75V at VIN in this configuration to power

the LTC2946. The 75V limitation is set by the zener clamp

D1 which protects the LTC2946 against voltage transients

exceeding 100V, while the 4V limitation is the minimum

operating voltage of the VDD pin. D1 can be removed if

the full voltage range of 100V is desired.

Figure 3a. DC2156A Is Powered from VIN

Figure 3b. LTC2946 Powered from VIN

SENSE– SENSE+ LOAD

LTC2946

5

dc2156af

DEMO MANUAL DC2156A

Hardware Setup Options

If JP1 is set to EXTVDD then VDD is powered by the

EXTVDD turret (Figure 4a and Figure 4b). Provide

a separate 4V to 100V at the EXTVDD turret in this

configuration. The maximum input VIN is limited to

75V by D1. D1 can be removed if the full voltage range

of 100V is desired.

Figure 4a. DC2156A Powered from External VDD

Figure 4b. LTC2946 Powered from External VDD

SENSE– SENSE+ LOAD

LTC2946

6

dc2156af

DEMO MANUAL DC2156A

If JP1 is settoINTVCC, thentheLTC2946’s internal circuitry

is powered from INTVCC. A low voltage supply (2.7V to

5.9V) connected to INTVCC helps minimize on-chip power

dissipation (Figure 5a and Figure 5b). The device can

also be used as a shunt regulator in this configuration to

monitor rails higher than 100V.

Regardlessofwhichconfigurationis selected, ifthe system

is connected properly, the green INTVCC LED should be lit.

By default the DC2156A is configured, with VIN providing

power to VDD.

In order to support a wide range of applications, the

LTC2946 demo board also features multiple nested sense

pads to support high current monitoring. These pads

are Kelvin sensed. By default the board supports current

monitoring of up to 5.12A. An appropriate sense resistor

can be used to support monitoring of desired current

levels up to 20A with an on-board sense resistor. The

SENSE+ and SENSE– turrets may be used to connect to

an external sense resistor and power path for any current

level. Remove RSNS in this case.

Figure 5a. DC2156A Powered from INTVCC

Figure 5b. LTC2946 Powered from INTVCC

LTC2946

Hardware Setup Options

7

dc2156af

DEMO MANUAL DC2156A

DC2156A Shunt Regulator

For supply voltages above 100V, the shunt regulator at

INTVCC can be used in both high and low side configurations

to provide power to the LTC2946 through an

external shunt resistor, RSHUNT. RSHUNT should be sized

according to the following equation:

VS(MAX) 5.9V

35mA

≤ RSHUNT ≤

VS(MIN) 6.7V

1mA +I

LOAD(MAX)

(1)

Figure 6a. Powering DC2156A from High Side Shunt Regulator to Allow for Input Voltage Higher than 100V

TO DC590

OR DC2026

+ LOAD –VIN

80V TO 200V

RSHUNT

Figure 6b. Powering LTC2946 from High Side Shunt Regulator to Allow for Input Voltage Higher than 100V

– SENSE– SENSE+ LOAD

LTC2946

where VS(MAX) and VS(MIN) are theoperatingmaximumand

minimum of the supply. ILOAD(MAX) is the maximum external

current load that is connected to the shunt regulator.

Figure 6a shows a high side power monitor with an input

monitoring range of 80V to 200V in a high side shunt

regulatorconfiguration. Thedevicegroundisseparatedfrom

circuit ground through RSHUNT and clamped at 6.3V below

the input supply, VIN. Note that due to the different ground

levels, the I2C signals from the LTC2946 need to be level

Hardware Setup Options

8

dc2156af

DEMO MANUAL DC2156A

Figure 7a. DC2156A Derives Power from Low Side Shunt Regulator in High Side Current Sense Topology

TO DC590

OR DC2026

LOAD

0V TO 75V

+

– 80V TO

200V

RSHUNT

5.1K

Figure 7b. DC2156A Derives Power from Low Side Shunt Regulator in High Side Current Sense Topology

SENSE– SENSE+ LOAD

LTC2946

Hardware Setup Options

shifted for communication with other ground referenced

components. The DC590, as well as the Linduino?, provide

the necessary isolation in this case. The bus voltage can be

measured with an appropriate external divider connected

to ADIN for full scale operation at 200V. Make sure to set

CA[7] intheCTRLAregister sothattheADCmeasuresADIN

with reference to INTVCC instead of the GND pin.

Figure 7a shows a high side rail-to-rail power monitor

which derives power from a greater than 100V secondary

supply. The voltage at INTVCC is clamped at 6.3V above

ground in a low side shunt regulator configuration to

power the part.

9

dc2156af

DEMO MANUAL DC2156A

Figure 8a. DC2156A Derives Power through Low Side Shunt Regulator in Low Side Current Sense Topology

VIN

80V TO

200V

RSHUNT

5.1k

+

– LOAD

TO DC590

OR DC2026

Figure 8b. LTC2946 Derives Power through Low Side Shunt Regulator in Low Side Current Sense Topology

SENSE+ SENSE–LOAD+

– LTC2946

RSNS

VIN

80V TO

200V

INTVCC

RSHUNT

5.1k

Hardware Setup Options

In low side power monitors, the device ground and the

current sense inputs are connectedtothenegative terminal

of the input supply as shown in Figure 8a. The low side

shunt regulator configuration allows operation with input

supplies above 100V by clamping the voltage at INTVCC.

10

dc2156af

DEMO MANUAL DC2156A

Figure 9a. Current Monitoring in a –48V System

–48V OUTPUT

–48V INPUT

RTN RTN

+

– LOAD

TO DC590

OR DC2026

Figure 9b. Current Monitoring in a –48V System

SENSE+ SENSE–+ LOAD ––48V RTN–48V INPUT –48V OUTPUT

LTC2946

RSNS

Hardware Setup Options

-48V System Monitoring

The DC2156A can also be configured to provide power

monitoring in -48V Telecom applications by setting JP1 to

EXTVDD, with the -48V input tied to VOUT and GND and the

-48V return tied to EXTVDD. The DC590 provides isolation

and level shifting, as the I2C interface is operating at -48V

with respect to -48V RTN, which is normally near earth

ground potential.

11

dc2156af

DEMO MANUAL DC2156A

Figure 10. Hardware Bench Setup

DC2156A

48V POWER SUPPLY

DC590

PC

GND VIN

5A ELECTRONIC LOAD

– +

– +

VOUT

GND

Quick Start Procedure

The various features of DC2156A can be demonstrated by

using Linear Technology’s QuikEval Software. QuikEval is

a USB-based product demonstration and data acquisition

software meant to be used in conjunction with the DC590

that connects to individual daughter cards for specific

Linear Technology products. This software can be found

on the Linear Technology website at:

http://ltspice.linear.com/software/ltcqev.exe

Connect the DC590 to the PC using the USB cable provided

with the DC590. Now, connect the DC590 to the DC2156A.

The setup should look like Figure 10.

Ensure power is applied to the DC2156A in any one of the

configurations described earlier in this manual and that a

load is connected to the board.

Oncesetupiscomplete, runtheQuikEvalSoftware. QuikEval

should auto-detect the DC2156A and provide the user with

a control panel.

Interfac ing with the DC2026

This board can also interface with the DC2026 Linduino

boardwhichispartoftheLinduinoFirmwareDevelopment

Program. The Linduino Firmware Development Program

provides users with convenient driver code, written in C,

for a wide range of LTC products. Please see the Linduino

page for more details.

The DC2026 comes preloaded with a DC590 emulator

firmware which allows easy interface with QuikEval. See

Figure 10 for connections but substitute the DC590 with

the DC2026. QuikEval will launch the GUI as it would with

the DC590. The DC2026 can also be used as a development

platform, example software along with drivers can

be found on the product landing page: http://www.linear.

com/product/LTC2946.

12

dc2156af

DEMO MANUAL DC2156A

The DC2156A software user interface was designed to

allow the user to quickly evaluate the LTC2946. The user

has the ability to set fault thresholds, enable/disable and

clear alerts, change the source for the VIN measurement as

well asmonitor voltage, current, power, charge andenergy.

RSNS is set to 20mΩ by default on the DC2156A, should

any changes be made on the board, the corresponding

value should be entered into the software control panel.

By pressing Start, the software interface will begin using

the DC590 for data collection.

The LTC2946 software UI is split up into two main components.

The Data Acquisition Terminal and a Tabbed

Interface. A screen shot of the GUI is shown in Figure 11.

Figure 11. LTC2946 Software UI

DC2156A SOFTWARE USER INTERFACE

Data Acquisition Terminal

The Data Acquisition Terminal display is always in view of

the user, providing convenient controls to quickly perform

common functions and displaying real time voltage, current,

power, charge and energy data.

The Data Acquisition Terminal consists of the following

components.

Performance Graph

The performance graph plots data in real time for up to

the last minute. Older data, once scrolled off the screen,

is discarded. The user can choose to log all the data in a

.csv file by clicking on the logging checkbox which is also

found on the Data Acquisition Terminal.

The performance graph can plot any two quantities from

VIN, Current, ADIN, Power, Energy andCharge concurrently

on the same plot. Radio buttons located next to the plot

allowtheusertoselectwhichquantity toploton a particular

axis. The axes are color coded. The left axis will always be

plotted lime green and the right axis will always be plotted

in red. These color codes are conveniently placed next to

the radio buttons for user reference.

13

dc2156af

DEMO MANUAL DC2156A

Note: You cannot plot the same quantity on both axes. Attempting

to do so will result in the next available quantity

being selected instead.

Measurement Panel

The measurement panel provides text based output of VIN

and ADIN registers in volts, current registers in amperes

and power registers in watts. For each quantity this panel

displays the values of the maximum and minimum registers,

the high and low limit threshold registers and the

real time reading register. These values get updated with

each polling of the device if there is any change.

Figure 13. Measurement Panel

DC2156A SOFTWARE USER INTERFACE

Figure 12. Performance Graph

14

dc2156af

DEMO MANUAL DC2156A

Accumulator Panel

The onboard accumulators have their own dedicated panel

which displays the charge, energy and time base register

values. The GUI takes this one step further by providing

the user with two extra text boxes which depict the average

current and power from the time the control panel initiated

the polling of the device. These values get updated with

each polling of the device if there is any change.

Figure 14. Accumulator Panel

ADIN Resistor Panel

The ADIN pin on the demo board has a resistive divider, in

the form of R2 and R10, which allows the user to measure

voltages up to 102V. Since the ADIN pin has a full-scale

voltage of 2.048V, the voltage displayed is scaled internally

by the GUI based on the values entered in the R2 and R10

text boxes. If the values of the onboard resistors changed,

then these text boxes should be updated to reflect that

change to get proper scaling. If no scaling is desired or if

the ADIN pin is to be connected directly to a voltage source

of up to 2.048V then the “R2 = 0 Ohms” checkbox can be

checked to eliminate the internal scaling presentin theGUI.

Figure 15. Resistor Menu

Setup and Quick Controls Panel

The Setup and Quick Controls panel allows the user to

quickly change the sense resistor value (this must match

the sense resistor present on the board), clear fault registers

as well as the maximum and minimum registers of

all quantities, set the device address, perform ARA in the

case of an alert, as well as put the part in snapshot mode.

There are two special checkboxes present in the Setup and

Quick Controls panel which require further explanation.

DC2156A SOFTWARE USER INTERFACE

Figure 16. Setup and Quick Controls

15

dc2156af

DEMO MANUAL DC2156A

The Logging checkbox, once checked, will enable the GUI

to store VIN, ADIN, current, power, energy and charge

register values in a user defined .csv file. It will also log

the value of the fault register (in hexadecimal) so that the

user can see at what particular instant the fault register

changed valueduring a fault. Note thatthis checkbox greys

out once the start button is clicked and must be selected

before the start button is clicked if logging is desired.

The Restore Accumulators checkbox enables the user to

individually clear accumulator overflow faults while still

retaining values. Each accumulator in the LTC2946 has its

own dedicated status and fault bits. Status bits represent

real-time status of the part. If a fault occurs and then goes

away, the status bit would get set and then reset with the

fault event. The fault bit would stay latched. The accumulator

status bits behave slightly differently in the sense that

they stay latched once an accumulator overflows and do

not get reset until the accumulator itself is reset. This is

because an accumulator is still in overflow state once it

rolls over until it is reset. The only way to reset the accumulators

is by setting bits CB[1:0] to either 10 or 11.

This however resets ALL of the accumulator registers. To

prevent this from happening and to allow the user to only

reset a single accumulator fault, the Restore Accumulators

checkbox first stores the information from all the

accumulators, resets the accumulators and then restores

the accumulator values in the accumulator registers which

were not selected to be reset.

Alert/Fault Mask LEDs

In order to provide a friendly user interface, the LTC2946

abstracts the ALERT mask and FAULT registers from the

user in the form of clickable LEDs. Each LED maps to a

corresponding bit in the ALERT and FAULT registers. For

example, the POWER OVERVALUE LED maps to bit 7 in

the ALERT1 and FAULT1 registers. Similarly, the GPIO1

Input Fault LED maps to Bit 6 in the ALERT2 and FAULT2

registers and so forth.

Figure 17. Alert/Fault Mark LEDs

The LEDs have three states which indicate the status of

the FAULT and ALERT registers.

AninactiveLED, representedwith a greycolor, indicatesthat

neither the alert bit nor the corresponding fault bit is set.

An armed LED, represented with a green color, indicates

that the corresponding alert bit has been set, however no

fault event has occurred. This arms the ALERT# pin to pull

low if that particular fault event occurs.

A faulted LED, represented with a red color, indicates

that the corresponding fault bit has been set. Clicking on

a faulted LED will clear that fault by resetting the corresponding

fault bit. The LED will then return to its previous

state whether it was inactive or armed.

DC2156A SOFTWARE USER INTERFACE

16

dc2156af

DEMO MANUAL DC2156A

Tab Interfac e

The tabbed interface allows the user to cycle between the

various control and threshold registers of the LTC2946

without losing view of the data. It consists of the following

three tabs.

Control Register A

As the name suggests, this tab gives the user direct access

to the CTRLA register in the form of radio buttons.

Here, the user can configure the ADIN pin reference, offset

calibration, voltage channel as well as the duty cycle of

measurements easily.

Control Register B and GPIO Control

This tab provides access to the CTRLB and allows

control of the GPIO pins through registers GPIO_CFG

and GPIO3_CTRL.

TheCTRLBregister canbeusedtoputthepartinshutdown

mode as well as to configure handling of fault events. The

state of the individual GPIO pins can also be configured

through this tab.

DC2156A SOFTWARE USER INTERFACE

Figure 19. Control Register B and GPIO Control

Figure 18. Control Register A

17

dc2156af

DEMO MANUAL DC2156A

DC2156A SOFTWARE USER INTERFACE

Threshold and Initial Values

This tab provides access to the threshold registers within

theLTC2946. Theuser cansetthemaximumandminimum

thresholds of power, current, VIN and ADIN here by entering

the desired value and then clicking the corresponding

button. Once thebuttonis clicked, thedata is first validated.

If it is out of range a message box will pop up and request

the user to enter data within the valid range. Once valid

data is sent to the part, the corresponding text box in the

MeasurementsPanelwillbeupdatedtoreflectthis change.

The user can also set the initial values for the accumulators

here. The time base is entered in hexadecimal format while

the charge and energy values are entered in coulombs and

joules, respectively. Similar to the threshold section, the

information must be sent by clicking on the corresponding

button so that the data is first validated and then sent

to the part.

This tab also allows the user to set the frequency of their

crystal oscillator if they are using one. The demo board

comes equipped with a 4MHz clock which is the default

value. If no external clock is desired, the crystal present on

the demo board can be removed and the “Use LTC2946’s

Internal Clock (5% Trimmed 250kHz)” checkbox can be

selected to use the part’s internal clock.

Figure 20. Threshold and Initial Values

18

dc2156af

DEMO MANUAL DC2156A

Parts List

ITEM QTY REFERENCE PART DESCRIPTION MANUFACTURER/PART NUMBER

Required Circuit Components

1 1 C1 CAP., X7R 0.1μF 200V 10% 1206 AVX, 12062C104KAT2A

2 2 C2, C5 CAP., X5R 0.1μF 25V 10% 0603 AVX, 06033D104KAT2A

3 2 C3, C4 CAP., C0G, 36pF 25V 5% 0603 AVX, 06033A360JAT2A

4 1 D1 VOLTAGE SUPPRESSOR, 70V Diodes/Zetex, SMAT70A

5 2 D2, D3 LED, GRN PLCC-2 (B-SIZE) Vishay, VLMC3101-GS08

6 1 D4 LED, AMBER PLCC-2 (B-SIZE) Vishay, VLMH3100-GS08

7 1 D5 LED, RED PLCC-2 (B-SIZE) Vishay, VLMS3000-GS08

8 1 D6 DIODE, DUAL SCHOTTKY, SOT-23 Fairchild, BAT54C

9 4 E1, E2, E3, E4 TP, TURRET, .094" Mill-Max, 2501-2-00-80-00-00-07-0

10 15 E5–E19 TP, TURRET, .064" Mill-Max, 2308-2-00-80-00-00-07-0

11 3 JP1, JP2, JP3 HEADERS, DBL. ROW 2 X 3 2mm CTRS. Sullins, NRPN032PAEN-RC

12 4 J1, J2, J3, J4 BANANA JACK, NON-INSULATED Keystone, 575-4

13 1 J5 CONN., HEADER, 14 PIN, 2mm Molex, 87831-1420

14 1 Q1 MOSFET N-CHAN,60V 115MA SOT23 Diodes/Zetex, 2N7002-7-F

15 1 RSNS RES., LRC 0.020Ω 1.0W 1% 2010 IRC, LRF20 10LF-01-R020-F

16 1 R1 RES., CHIP 51Ω 0.1W 5% 0603 Vishay, CRCW060351R0JNEA

17 1 R2 RES., CHIP 147k 0.1W 1% 0603 Vishay, CRCW0603147KFKEA

18 4 R3, R5, R7, R9 RES., CHIP 3.3k 0.1W 5% 0603 Vishay, CRCW06033K30JNEA

19 3 R4, R6, R8 RES., CHIP 100k 0.1W 5% 0603 Vishay, CRCW0603100KJNEA

20 1 R10 RES., CHIP 3k 0.1W 1% 0603 Vishay, CRCW06033K00FKEA

21 0 R11, R12 RES, 0603 Opt

22 1 R14 RES, 0Ω, 0603 Vishay, CRCW0603000JNEA

23 3 R15, R16, R17 RES., CHIP 5.1k 0.1W 5% 0603 Vishay, CRCW06035K10JNEA

24 1 U1 I.C., POWER MONITOR, DFN16DE-4X3 Linear Technology, LTC2946IDE

25 1 U2 I.C., SERIAL EEPROM TSSOP-8 Microchip, 24LC025-I/ST

26 1 Y1 XTAL, 4 MHz, Y-ABLS Abracon Corp., ABLS-4.000MHz-B2-T

28 3 SHUNTS AS SHOWN ON ASSY DWG SHUNT, 2mm CTRS. Samtec 2SN-BK-G

29 4 MH1–MH4 STAND-OFF, NYLON 0.25" Keystone, 8831 (SNAP ON)

19

dc2156af

DEMO MANUAL DC2156A

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.

Figure 21. DC2156A Demo Circuit Schematic

Schematic Diagram

NOTES: UNLESS OTHERWISE SPECIFIED

1. ALL RESISTORS ARE IN OHMS, 0603.

ALL CAPACITORS ARE IN MICROFARADS, 0603.

2. INSTALL SHUNTS AS SHOWN.

NOTE: EEPROM FOR BOARD IDENTIFICATION

DC590 I2C INTERFACE

* DEFAULT

JUMPER POSITIONS

REMOVE R14 TO SEPERATE SDAI AND SDAO

TO DC590B

VOUT VIN

INTVCC

INTVCC

VGPIO

VGPIO

VPU

VPU

VPU

SIZE

DATE:

IC NO. REV.

SHEET OF

TITLE:

APPROVALS

PCB DES.

APP ENG.

TECHNOLOGY

1630 McCarthy Blvd.

Milpitas, CA 95035

Phone: (408)432-1900

Fax: (408)434-0507

LTC Confidential-For Customer Use Only

CUSTOMER NOTICE

LINEAR TECHNOLOGY HAS MADE A BEST EFFORT TO DESIGN A

CIRCUIT THAT MEETS CUSTOMER-SUPPLIED SPECIFICATIONS;

HOWEVER, IT REMAINS THE CUSTOMER'S RESPONSIBILITY TO

VERIFY PROPER AND RELIABLE OPERATION IN THE ACTUAL

APPLICATION. COMPONENT SUBSTITUTION AND PRINTED

CIRCUIT BOARD LAYOUT MAY SIGNIFICANTLY AFFECT CIRCUIT

PERFORMANCE OR RELIABILITY. CONTACT LINEAR

TECHNOLOGY APPLICATIONS ENGINEERING FOR ASSISTANCE.

THIS CIRCUIT IS PROPRIETARY TO LINEAR TECHNOLOGY AND

SCHEMATIC

SUPPLIED FOR USE WITH LINEAR TECHNOLOGY PARTS. SCALE = NONE

www.linear.com

2 DEMO CIRCUIT 2156A

05/28/2014, 05:25 PM 1 1

WIDE RANGE I2C POWER MONITOR

N/A

LTC2946IDE

KIM T.

SAL H.

WITH ENERGY AND COULOMB METER

SIZE

DATE:

IC NO. REV.

SHEET OF

TITLE:

APPROVALS

PCB DES.

APP ENG.

TECHNOLOGY

1630 McCarthy Blvd.

Milpitas, CA 95035

Phone: (408)432-1900

Fax: (408)434-0507

LTC Confidential-For Customer Use Only

CUSTOMER NOTICE

LINEAR TECHNOLOGY HAS MADE A BEST EFFORT TO DESIGN A

CIRCUIT THAT MEETS CUSTOMER-SUPPLIED SPECIFICATIONS;

HOWEVER, IT REMAINS THE CUSTOMER'S RESPONSIBILITY TO

VERIFY PROPER AND RELIABLE OPERATION IN THE ACTUAL

APPLICATION. COMPONENT SUBSTITUTION AND PRINTED

CIRCUIT BOARD LAYOUT MAY SIGNIFICANTLY AFFECT CIRCUIT

PERFORMANCE OR RELIABILITY. CONTACT LINEAR

TECHNOLOGY APPLICATIONS ENGINEERING FOR ASSISTANCE.

THIS CIRCUIT IS PROPRIETARY TO LINEAR TECHNOLOGY AND

SCHEMATIC

SUPPLIED FOR USE WITH LINEAR TECHNOLOGY PARTS. SCALE = NONE

www.linear.com

2 DEMO CIRCUIT 2156A

05/28/2014, 05:25 PM 1 1

WIDE RANGE I2C POWER MONITOR

N/A

LTC2946IDE

KIM T.

SAL H.

WITH ENERGY AND COULOMB METER

SIZE

DATE:

IC NO. REV.

SHEET OF

TITLE:

APPROVALS

PCB DES.

APP ENG.

TECHNOLOGY

1630 McCarthy Blvd.

Milpitas, CA 95035

Phone: (408)432-1900

Fax: (408)434-0507

LTC Confidential-For Customer Use Only

CUSTOMER NOTICE

LINEAR TECHNOLOGY HAS MADE A BEST EFFORT TO DESIGN A

CIRCUIT THAT MEETS CUSTOMER-SUPPLIED SPECIFICATIONS;

HOWEVER, IT REMAINS THE CUSTOMER'S RESPONSIBILITY TO

VERIFY PROPER AND RELIABLE OPERATION IN THE ACTUAL

APPLICATION. COMPONENT SUBSTITUTION AND PRINTED

CIRCUIT BOARD LAYOUT MAY SIGNIFICANTLY AFFECT CIRCUIT

PERFORMANCE OR RELIABILITY. CONTACT LINEAR

TECHNOLOGY APPLICATIONS ENGINEERING FOR ASSISTANCE.

THIS CIRCUIT IS PROPRIETARY TO LINEAR TECHNOLOGY AND

SCHEMATIC

SUPPLIED FOR USE WITH LINEAR TECHNOLOGY PARTS. SCALE = NONE

www.linear.com

2 DEMO CIRCUIT 2156A

05/28/2014, 05:25 PM 1 1

WIDE RANGE I2C POWER MONITOR

N/A

LTC2946IDE

KIM T.

SAL H.

WITH ENERGY AND COULOMB METER

REVISION HISTORY

DESCRIPTION DATE APPROVED ECO REV

SAL H. PRODUCTION __ 2 05-28-14

REVISION HISTORY

DESCRIPTION DATE APPROVED ECO REV

SAL H. PRODUCTION __ 2 05-28-14

REVISION HISTORY

DESCRIPTION DATE APPROVED ECO REV

SAL H. PRODUCTION __ 2 05-28-14 E19

DEMO MANUAL DC2156A

Linear Technology Corporation

1630 McCarthy Blvd., Milpitas, CA 95035-7417

(408) 432-1900 ● FAX: (408) 434-0507 ● www.linear.com? LINEAR TECHNOLOGY CORPORATION 2014

LT 0814 ? PRINTED IN USA

DEMONSTRATION BOARD IMPORTANT NOTICE

Linear Technology Corporation (LTC) provides the enclosed product(s) under the following AS IS conditions:

This demonstration board (DEMO BOARD) kit being sold or provided by Linear Technology is intended for use for ENGINEERINGDEVELOPMENT

OR EVALUATION PURPOSES ONLY and is not provided by LTC for commercial use. As such, the DEMO BOARD herein may not be complete

in terms of required design-, marketing-, and/or manufacturing-related protective considerations, including but not limited to product safety

measures typically found in finished commercial goods. As a prototype, this product does not fall within the scope of the European Union

directive on electromagnetic compatibility and therefore may or may not meet the technical requirements of the directive, or other regulations.

If this evaluation kit does not meet the specifications recited in the DEMO BOARD manual the kit may be returned within 30 days from the date

of delivery for a full refund. THE FOREGOING WARRANTY IS THE EXCLUSIVE WARRANTY MADE BY THE SELLER TO BUYER AND IS IN LIEU

OF ALL OTHER WARRANTIES, EXPRESSED, IMPLIED, OR STATUTORY, INCLUDING ANY WARRANTY OF MERCHANTABILITY OR FITNESS

FOR ANY PARTICULAR PURPOSE. EXCEPT TO THE EXTENT OF THIS INDEMNITY, NEITHER PARTY SHALL BE LIABLE TO THE OTHER FOR

ANY INDIRECT, SPECIAL, INCIDENTAL, OR CONSEQUENTIAL DAMAGES.

The user assumes all responsibility and liability for proper and safe handling of the goods. Further, the user releases LTC from all claims

arising from the handling or use of the goods. Due to the open construction of the product, it is the user’s responsibility to take any and all

appropriate precautions with regard to electrostatic discharge. Also be aware that the products herein may not be regulatory compliant or

agency certified (FCC, UL, CE, etc.).

No License is granted under any patent right or other intellectual property whatsoever. LTC assumes no liability for applications assistance,

customer product design, software performance, or infringement of patents or any other intellectual property rights of any kind.

LTC currently services a variety of customers for products around the world, and therefore this transaction is not exclusive.

Please read the DEMO BOARD manual prior to handling the product. Persons handling this product must have electronics training and

observe good laboratory practice standards. Common sense is encouraged.

This notice contains important safety information about temperatures and voltages. For further safety concerns, please contact a LTC application

engineer.

Mailing Address:

Linear Technology

1630 McCarthy Blvd.

Milpitas, CA 95035

Copyright 2004, Linear Technology Corporation