MCP6V06T-E/SN Microchip Technology, MCP6V06T-E/SN Datasheet - Page 29

MCP6V06T-E/SN

Manufacturer Part Number

MCP6V06T-E/SN

Description

Single, Auto-Zero Op Amp, E Temp 8 SOIC 3.90mm (.150") T/R

Manufacturer

Microchip Technology

Datasheet

1.MCP6V06T-EMNY.pdf (44 pages)

Specifications of MCP6V06T-E/SN

Amplifier Type

Chopper (Zero-Drift)

Number Of Circuits

Output Type

Rail-to-Rail

Slew Rate

0.5 V/µs

Gain Bandwidth Product

1.3MHz

Current - Input Bias

6pA

Voltage - Input Offset

3µV

Current - Supply

300µA

Current - Output / Channel

22mA

Voltage - Supply, Single/dual (±)

1.8 V ~ 5.5 V

Operating Temperature

-40°C ~ 125°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (3.9mm Width)

Number Of Channels

Voltage Gain Db

158 dB

Common Mode Rejection Ratio (min)

120 dB

Input Offset Voltage

0.003 mV

Operating Supply Voltage

3 V, 5 V

Maximum Operating Temperature

+ 125 C

Mounting Style

SMD/SMT

Minimum Operating Temperature

- 40 C

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

-3db Bandwidth

Lead Free Status / Rohs Status

Details

Other names

MCP6V06T-E/SNTR

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

MCP6V06T-E/SN

Manufacturer:

MICROCHIP

Quantity:

12 000

Current page: 29 of 44
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4.4

4.4.1

Many sensors are configured as Wheatstone bridges.

Strain gauges and pressure sensors are two common

examples. These signals can be small and the

common mode noise large. Amplifier designs with high

differential gain are desirable.

Figure 4-15

bridge with a minimum of components. Because the

circuit is not symmetric, the ADC input is single ended,

and there is a minimum of filtering, the CMRR is good

enough for moderate common mode noise.

FIGURE 4-15:

Figure 4-16

Wheatstone bridges. This circuit is symmetric and has

high CMRR. Using a differential input to the ADC helps

with the CMRR.

FIGURE 4-16:

R R

Typical Applications

WHEATSTONE BRIDGE

shows how to interface to a Wheatstone

shows a higher performance circuit for

10 nF

0.2R

Simple Design.

High Performance Design.

1 µF

200Ω

200 Ω

0.01C

100R

MCP6V06

20 kΩ

3 kΩ

1 µF

3 kΩ

½ MCP6V07

ADC

4.4.2

The ratiometric circuit in

wire RTD. It corrects for the sensor’s wiring resistance

by subtracting the voltage across the middle R

top R1 does not change the output voltage; it balances

the op amp inputs. Failure (open) of the RTD is

detected by an out-of-range voltage.

FIGURE 4-17:

The voltages at the input of the ADC can be calculated

with the following:

Where:

100Ω

RTD

RTD SENSOR

10 nF

------------------------------------------------------------------------------

RTD

MCP6V06/7/8

2 R

Voltage at the top of R

Voltage at the bottom of R

Voltage across top and middle

ADC’s common mode input

ADC’s differential mode input

20 kΩ

⋅

(

–

RTD Sensor.

’s

1 µF

2.49 kΩ

Figure 4-17

2.49 kΩ

–

⁄

(

⁄

RTD

)

2.55 kΩ

1 G

100 kΩ

100 nF

DS22093B-page 29

conditions a three

–

½ MCP6V07

RTD

3 kΩ

ADC

. The

MCP6V06T-E/SN Microchip Technology, MCP6V06T-E/SN Datasheet - Page 29

MCP6V06T-E/SN

Specifications of MCP6V06T-E/SN

Available stocks

Related parts for MCP6V06T-E/SN