MCP6V06T-E/MNY Microchip Technology, MCP6V06T-E/MNY Datasheet - Page 26

MCP6V06T-E/MNY

Manufacturer Part Number

MCP6V06T-E/MNY

Description

IC OPAMP AUTO-ZERO SGL 8-TDFN

Manufacturer

Microchip Technology

Datasheet

1.MCP6V06T-EMNY.pdf (44 pages)

Specifications of MCP6V06T-E/MNY

Slew Rate

0.5 V/µs

Amplifier Type

Chopper (Zero-Drift)

Number Of Circuits

Output Type

Rail-to-Rail

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-TDFN

Op Amp Type

Precision

No. Of Amplifiers

Bandwidth

1.3MHz

Supply Voltage Range

1.8V To 5.5V

Amplifier Case Style

TQFN

No. Of Pins

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/MNYTR

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

MCP6V06T-E/MNY

Manufacturer:

Microchip Technology

Quantity:

135

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

MCP6V06T-E/MNY

Manufacturer:

MICROCHIP

Quantity:

12 000

Current page: 26 of 44
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MCP6V06/7/8

4.3.9

In order to achieve DC precision on the order of ±1 µV,

many physical errors need to be minimized. The design

of the Printed Circuit Board (PCB), the wiring, and the

thermal environment has a strong impact on the

precision achieved. A poor PCB design can easily be

more than 100 times worse than the MCP6V06/7/8 op

amps minimum and maximum specifications.

4.3.9.1

Any time two dissimilar metals are joined together, a

temperature dependent voltage appears across the

junction (the Seebeck or thermo-junction effect). This

effect is used in thermocouples to measure tempera-

ture. The following are examples of thermo-junctions

on a PCB:

• Components (resistors, op amps, …) soldered to

• Wires mechanically attached to the PCB

• Jumpers

• Solder joints

• PCB vias

Typical thermo-junctions have temperature to voltage

conversion coefficients of 10 to 100 µV/°C (sometimes

higher).

There are three basic approaches to minimizing

thermo-junction effects:

• Minimize thermal gradients

• Cancel thermo-junction voltages

• Minimize difference in thermal potential between

DS22093B-page 26

a copper pad

metals

PCB DESIGN FOR DC PRECISION

Thermo-junctions

4.3.9.2

Figure 4-11

and inverting gain amplifier circuits on one schematic.

Usually, to minimize the input bias current related off-

set, R

The guard traces (with ground vias at the ends) help

minimize the thermal gradients. The resistor layout

cancels the resistor thermal voltages, assuming the

temperature gradient is constant near the resistors:

EQUATION 4-2:

FIGURE 4-11:

for Single Non-inverting and Inverting Amplifiers.

Where:

Note:

is chosen to be R

Changing the orientation of the resistors

will usually cause a significant decrease in

the cancellation of the thermal voltages.

shows the recommended non-inverting

MCP6V06

Non-inverting and Inverting Amplifier

Layout for Thermo-junctions

OUT

1 + G

magnitude

≈ -V

≈ V

is neglected

, inverting gain magnitude

, non-inverting gain

PCB Layout and Schematic

||R

, V

= GND

OUT

MCP6V06T-E/MNY Microchip Technology, MCP6V06T-E/MNY Datasheet - Page 26

MCP6V06T-E/MNY

Specifications of MCP6V06T-E/MNY

Available stocks

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