MCP6V01RD-TCPL Microchip Technology, MCP6V01RD-TCPL Datasheet - Page 27
MCP6V01RD-TCPL
Manufacturer Part Number
MCP6V01RD-TCPL
Description
REF DESIGN THERMCPL FOR MCP6V01
Manufacturer
Microchip Technology
Datasheets
1.MCP6V01RD-TCPL.pdf
(44 pages)
2.MCP6V01RD-TCPL.pdf
(30 pages)
3.MCP6V03-ESN.pdf
(40 pages)
Specifications of MCP6V01RD-TCPL
Channels Per Ic
1 - Single
Amplifier Type
Chopper (Zero-Drift)
Output Type
Rail-to-Rail
Slew Rate
0.5 V/µs
Current - Output / Channel
22mA
Operating Temperature
-40°C ~ 125°C
Voltage - Supply, Single/dual (±)
1.8 V ~ 5.5 V
Board Type
Fully Populated
Utilized Ic / Part
MCP6V01
Silicon Manufacturer
Microchip
Silicon Core Number
MCP6V01
Kit Application Type
Sensing - Temperature
Application Sub Type
Temperature Sensor
Processor To Be Evaluated
MCP6V01
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
-3db Bandwidth
-
Current - Supply (main Ic)
-
Lead Free Status / Rohs Status
Lead free / RoHS Compliant
4.3.9.3
Figure 4-12
fier circuit. Usually, we choose 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 4-3:
FIGURE 4-12:
for Single Difference Amplifier.
© 2008 Microchip Technology Inc.
Where:
Thermal voltages are approximately equal
Note:
V
G
V
M
P
DM
V
V
M
P
Changing the orientation of the resistors
will usually cause a significant decrease in
the cancellation of the thermal voltages.
shows the recommended difference ampli-
V
V
=
MCP6V01
Difference Amplifier Layout for
Thermo-junctions
OUT
OUT
R4
R2
R1
R3
R
V
R
≈ V
≈ V
R
3
OS
1
2
/R
U
REF
REF
is neglected
1
1
PCB Layout and Schematic
= R
+ (V
+ (V
4
R
R
/R
P
P
4
3
U1
2
– V
– V
, difference gain
1
= R
M
M
V
)G
)G
2
REF
DM
DM
V
and R
OUT
V
V
3
OUT
REF
= R
4
.
4.3.9.4
The dual op amp amplifiers shown in
Figure 4-17
greater than 1, and a common mode gain of 1 .They
can use the layout shown in
ting resistors (R
bined so that the thermal voltages can be canceled.
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 4-4:
FIGURE 4-13:
for Dual Non-inverting Amplifier.
Where:
Thermal voltages are approximately equal
Note:
G
G
R3
R2
R1
DM
CM
V
V
IA
IB
=
=
Changing the orientation of the resistors
will usually cause a significant decrease in
the cancellation of the thermal voltages.
(V
(V
produce a non-inverting difference gain
Dual Non-inverting Amplifier Layout
for Thermo-junctions
½ MCP6V02
½ MCP6V02
OA
OA
1 + R
1, common mode gain
V
2
) between the two sides are not com-
OS
– V
+ V
V
MCP6V01/2/3
is neglected
3
OB
OA
OB
R
R
R
R
/R
V
PCB Layout and Schematic
1
1
2
2
IA
U1
) ≈ (V
)/2 ≈ (V
2
U
U
, differential mode gain
1
1
V
Figure
IA
IB
IA
– V
R
R
V
3
3
+ V
OB
IB
4-13. The gain set-
DS22058C-page 27
)G
IB
Figure 4-16
)/2
DM
V
V
OA
OB
R3
R2
R1
and
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