MCP603T-E/CH - MICROCHIP

MCP601/1R/2/3/4

Features

• Single-Supply: 2.7V to 6.0V

• Rail-to-Rail Output

• Input Range Includes Ground

• Gain Bandwidth Product: 2.8 MHz (typical)

• Unity-Gain Stable

• Low Quiescent Current: 230 µA/amplifier (typical)

• Chip Select (CS): MCP603 only

• Temperature Ranges:

- Industrial: -40°C to +85°C

- Extended: -40°C to +125°C

• Available in Single, Dual, and Quad

Typical Applications

• Portable Equipment

• A/D Converter Driver

• Photo Diode Pre-amp

• Analog Filte r s

• Data Acquisition

• Notebooks and PDAs

• Sensor Interface

Available Tools

• SPICE Macro Models

• FilterLab® Software

• Mindi™ Simulation Tool

• MAPS (Microchip Advanced Part Selector)

• Analog Demonstration and Evaluation Boards

• Application Notes

Description

The Microchip Technology Inc. MCP601/1R/2/3/4

family of low-power operational amplifiers (op amps)

are offered in single (MCP601), single with Chip Select

(CS) (MCP603), dual (MCP602), an d quad (MCP604)

configurations. These op amps utilize an advanced

CMOS technology that provides low bias current, high-

speed operation, high open-loop gain, and rail-to-rail

output swing. This product offering operates with a

single supply voltage that can be as low as 2.7V, while

drawing 230 µA (typical) of quiescent current per

amplifier. In addition, the common mode input voltage

range goes 0.3V below ground, making these

amplifiers ideal for single-supply operation.

These devices are appropriate for low power, battery

operated circuits due to the low quiescent current, for

A/D convert driver amplifiers because of their wide

bandwidth or for anti-aliasing filters by virtue of their low

input bias current.

The MCP601, MCP602, an d MCP603 are available in

standard 8-lead PDIP, SOIC, and TSSOP packages.

The MCP601 and MCP601R are also available in a

standard 5-lead SOT -23 package, while the MCP603 is

available in a standard 6-lead SOT-23 package. The

MCP604 is offered in standard 14-lead PDIP, SOIC,

and TSSOP packages.

The MCP601/1R/2/3/4 family is available in the

Industrial and Extended temperature ranges and has a

power supply range of 2.7V to 6.0V.

Package Types

VIN+

VIN–

VSS

VOUT

VDD

VINA+

VINA–

VDD

VINC+

VSS

VOUTC

VINC–

VOUTA

VINB+

VIND–

VOUTD

VOUTB

VINB–

VIND+

VINA+

VINA–

VSS

VINB–

VOUTB

VDD

VINB+

VOUTA

MCP601

PDIP, SOIC, TSSOP

MCP604

PDIP, SOIC, TSSOP

MCP602

PDIP, SOIC, TSSOP

VIN+

VSS VIN–

VDD

VOUT

MCP601

SOT23-5

VIN+

VSS VIN–

VDD

VOUT

MCP603

SOT23-6

VIN+

VIN–

VSS

VOUT

VDD

MCP603

PDIP, SOIC, TSSOP

VIN+

VDD VIN–

VSS

VOUT

MCP601R

SOT23-5

2.7V to 6.0V Single Supply CMOS Op Amps

MCP601/1R/2/3/4

1.0 ELECTRICAL

CHARACTERISTICS

Absolute Maximum Ratings †

VDD –V

SS ........................................................................7.0V

Current at Input Pins.....................................................±2 mA

Analog Inputs (VIN+, VIN–) †† ........ VSS –1.0VtoV

DD +1.0V

All Other Inputs and Outputs ......... VSS – 0.3V to VDD +0.3V

Difference Input Voltage ...................................... |VDD –V

SS|

Output Short Circuit Current .................................Continuous

Current at Output and Supply Pins ............................±30 mA

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

Maximum Junction Temperature (TJ)..........................+150°C

ESD Protection On All Pins (HBM; MM).............. ≥ 3 kV; 200V

† Notice: Stresses above those listed under “Absolute

Maximum Ratings” may cause permanent damage to the

device. This is a stress rating only and functional operation of

the device at those or any other conditions above those

indicated in the operational listings of this specification is not

implied. Exposure to maximum rating conditions for extended

periods may affect device reliability.

†† See Section 4.1.2 “Input Voltage and Current Limits”.

DC CHARACTERISTICS

Electrical Specifications: Unless otherwise specified, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2,

VOUT ≈ VDD/2, VL = VDD/2, and RL = 100 kΩ to VL, and CS is tied low. (Refer to Figure 1-2 and Figure 1-3).

Parameters Sym Min Typ Max Units Conditions

Input Offset

Input Offset Voltage VOS -2 ±0.7 +2 mV

Industrial Temperature VOS -3 ±1 +3 mV TA = -40°C to +85°C (Note 1)

Extended Temperature VOS -4.5 ±1 +4.5 mV TA = -40°C to +125°C (Note 1)

Input Offset Temperature Drift ΔVOS/ΔTA—±2.5—µV/°CT

A = -40°C to +125°C

Power Supply Rejection PSRR 80 88 — dB VDD = 2.7V to 5.5V

Input Current and Impedance

Input Bias Current IB—1—pA

Industrial Temperature IB—2060pAT

A = +85°C (Note 1)

Extended Temperature IB— 450 5000 pA TA = +125°C (Note 1)

Input Offset Current IOS —±1—pA

Common Mode Input Impedance ZCM —1013||6 —Ω||pF

Differential Input Impedance ZDIFF —1013||3 —Ω||pF

Common Mode

Common Mode Input Range VCMR VSS – 0.3 — VDD – 1.2 V

Common Mode Rejection Ratio CMRR 75 90 — dB VDD = 5.0V, VCM = -0.3V to 3.8V

Open-loop Gain

DC Open-loop Gain (large signal) AOL 100 115 — dB RL = 25 kΩ to VL,

VOUT = 0.1V to VDD – 0.1V

AOL 95 110 — dB RL = 5 kΩ to VL,

VOUT = 0.1V to VDD – 0.1V

Output

Maximum Output Voltage Swing VOL, VOH VSS + 15 — VDD – 20 mV RL = 25 kΩ to VL, Output overdrive = 0.5V

VOL, VOH VSS + 45 — VDD – 60 mV RL = 5 kΩ to VL, Output overdrive = 0.5V

Linear Output Voltage Swing VOUT VSS + 100 — VDD – 100 mV RL = 25 kΩ to VL, AOL ≥ 100 dB

VOUT VSS + 100 — VDD – 100 mV RL = 5 kΩ to VL, AOL ≥ 95 dB

Output Short Circuit Current ISC —±22—mAV

DD = 5.5V

ISC —±12—mAV

DD = 2.7V

Power Supply

Supply Voltage VDD 2.7 — 6.0 V (Note 2)

Quiescent Current per Amplifier IQ— 230 325 µA IO = 0

Note 1: These specifications are not tested in either the SOT-23 or TSSOP packages with date codes older than YYWW = 0408.

In these cases, the minimum and maximum values are by design and characterization only.

2: All parts with date codes November 2007 and later have been screened to ensure operation at VDD=6.0V. However, the

other minimum and maximum specifications are measured at 1.4V and/or 5.5V.

MCP601/1R/2/3/4

AC CHARACTERISTICS

MCP603 CHIP SELECT (CS) CHARACTERISTICS

FIGURE 1-1: MCP603 Chip Select (CS)

Timing Diagram.

Electrical Specifications: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2,

VOUT ≈ VDD/2, VL = VDD/2, and RL = 100 kΩ to VL, CL = 50 pF, and CS is tied low. (Refer to Figure 1-2 and Figure 1-3).

Parameters Sym Min Typ Max Units Conditions

Frequency Response

Gain Bandwidth Product GBWP — 2.8 — MHz

Phase Margin PM — 50 — ° G = +1 V/V

Step Response

Slew Rate SR — 2.3 — V/µs G = +1 V/V

Settling Time (0.01%) tsettle — 4.5 — µs G = +1 V/V, 3.8V step

Noise

Input Noise Voltage Eni —7—µV

P-P f = 0.1 Hz to 10 Hz

Input Noise Voltage Density eni —29—nV/√Hz f = 1 kHz

eni —21—nV/√Hz f = 10 kHz

Input Noise Current Density ini —0.6—fA/√Hz f = 1 kHz

Electrical Specifications: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2,

VOUT ≈ VDD/2, VL = VDD/2, and RL = 100 kΩ to VL, CL = 50 pF, and CS is tied low. (Refer to Figure 1-2 and Figure 1-3).

Parameters Sym Min Typ Max Units Conditions

CS Low Specifications

CS Logic Threshold, Low VIL VSS — 0.2 VDD V

CS Input Current, Low ICSL -1.0 — — µA CS = 0.2VDD

CS High Specifications

CS Logic Threshold, High VIH 0.8 VDD —V

DD V

CS Input Current, High ICSH —0.72.0µACS = VDD

Shutdown VSS current IQ_SHDN -2.0 -0.7 — µA CS = VDD

Amplifier Output Leakage in Shutdown IO_SHDN —1—nA

Timing

CS Low to Amplifier Output Turn-on Time tON —3.110µsCS ≤ 0.2VDD, G = +1 V/V

CS High to Amplifier Output High-Z Time tOFF —100—nsCS ≥ 0.8VDD, G = +1 V/V, No load.

Hysteresis VHYST —0.4—VV

DD = 5.0V

CS tOFF

VOUT

tON

Hi-Z Hi-Z

IDD 2nA 230 µA

Output Active

ISS -700 nA -230 µA

CS 700 nA 2nA

Current

(typical) (typical)

MCP601/1R/2/3/4

1.1 Test Circuits

The test circuits used for the DC and AC tests are

shown in Figure 1-2 and Figure 1-2. The bypass

capacitors are laid out according to the rules discussed

in Section 4.5 “Supply Bypass”.

FIGURE 1-2: AC and DC Test Circuit for

Most Non-Inverting Gain Conditions.

FIGURE 1-3: AC and DC Test Circuit for

Most Inverting Gain Conditions.

TEMPERATURE CHARACTERISTICS

Electrical Specifications: Unless otherwise indicated, VDD = +2.7V to +5.5V and VSS = GND.

Parameters Sym Min Typ Max Units Conditions

Temperature Ranges

Specified Temperature Range TA-40 — +85 °C Industrial temperature parts

TA-40 — +125 °C Extended temperature parts

Operating Temperature Range TA-40 — +125 °C Note

Storage Tempera ture Range TA-65 — +150 °C

Thermal Package Resistances

Thermal Resistance, 5L-SOT23 θJA —256—°C/W

Thermal Resistance, 6L-SOT23 θJA —230—°C/W

Thermal Resistance, 8L-PDIP θJA —85—°C/W

Thermal Resistance, 8L-SOIC θJA —163—°C/W

Thermal Resistance, 8L-TSSOP θJA —124—°C/W

Thermal Resistance, 14L-PDIP θJA —70—°C/W

Thermal Resistance, 14L-SOIC θJA —120—°C/W

Thermal Resistance, 14L-TSSOP θJA —100—°C/W

Note: The Industrial temperature parts operate over this extended range, but with reduced performance. The

Extended temperature specs do not apply to Industrial temperature parts. In any case, the internal Junction

temperature (TJ) must not exceed the absolute maximum specification of 150°C.

VDD

MCP60X

RGRF

RNVOUT

VIN

VDD/2

1µF

CLRL

0.1 µF

VDD

MCP60X

RGRF

RNVOUT

VDD/2

VIN

1µF

CLRL

0.1 µF

MCP601/1R/2/3/4

2.0 TYPICAL PERFORMANCE CURVES

Note: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2, VOUT ≈ VDD/2,

VL = VDD/2, RL = 100 kΩ to VL, CL = 50 pF and CS is tied low.

FIGURE 2-1: Open-Loop Gain, Phase vs.

Frequency.

FIGURE 2-2: Slew Rate vs. Temperature.

FIGURE 2-3: Gain Bandwidth Product,

Phase Margin vs. Temperature.

FIGURE 2-4: Quiescent Current vs.

Supply Voltage.

FIGURE 2-5: Quiescent Current vs.

Temperature.

FIGURE 2-6: Input Noise Voltage Density

vs. Frequency.

Note: The graphs and tables provided following this note are a statistical summary based on a limited number of

samples and are provide d for informational purposes only. The performance characteristics listed herein

are not tested or guaranteed. In some graphs or tables, the data presented may be outside the specified

operating range (e.g., outside specified pow er supply range) and therefore outside the warranted range.

-40

-20

100

120

1.E-

1.E+

Frequency (Hz)

Open-Loop Gain (dB)

-240

-210

-180

-150

-120

-90

-60

-30

Open-Loop Phase (°)

0.1 1 10 100 1k 10k 100k 1M 10M

Gain

Phase

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

-50-25 0 255075100125

Ambient Temperature (°C)

Slew Rate (V/µs)

Rising Edge

Falling Edge

VDD = 5.0V

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

-50 -25 0 25 50 75 100 125

Ambient Temperature (°C)

Gain Bandwidth Product

(MHz)

100

110

Phase Margin, G = +1 (°)

GBWP

PM, G = +1

100

150

200

250

300

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5

Supply Voltage (V)

Quiescent Current

per Amplifier (µA)

IO = 0

TA = -40°C

TA = +25°C

TA = +85°C

TA = +125°C

100

150

200

250

300

-50-250 255075100125

Ambient Temperature (°C)

Quiescent Current

per Amplifier (µA)

VDD = 2.7V

VDD = 5.5V

IO = 0

1.E+01

1.E+02

1.E+03

1.E+04

1.E-

1.E+0

6Frequency (Hz)

Input Noise Voltage Density

(V/√Hz)

0.1 1 10 100 1k 10k 100k 1M

10µ

1µ

100n

10n

MCP601/1R/2/3/4

Note: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2, VOUT ≈ VDD/2,

VL = VDD/2, RL = 100 kΩ to VL, CL = 50 pF and CS is tied low.

FIGURE 2-7: Input Offset Vo ltage.

FIGURE 2-8: Input Offset Voltage vs.

Temperature.

FIGURE 2-9: Input Offset Voltage vs.

Common Mode Input Vo ltage with VDD = 2.7V.

FIGURE 2-10: Input Offset Voltage Drift.

FIGURE 2-11: CMRR, PSRR vs.

Temperature.

FIGURE 2-12: Input Offset Voltage vs.

Common Mode Input Voltage with VDD = 5.5V.

10%

12%

14%

16%

-2.0 -1.6 -1.2 -0.8 -0.4 0.0 0.4 0.8 1.2 1.6 2.0

Input Offset Voltage (mV)

Percentage of Occurrences

1200 Samples

-0.5

-0.4

-0.3

-0.2

-0.1

0.0

0.1

0.2

0.3

0.4

0.5

-50 -25 0 25 50 75 100 125

Ambient Temperature (°C)

Input Offset Voltage (mV)

VDD = 2.7V

VDD = 5.5V

-200

-100

100

200

300

400

500

600

700

800

-0.4

-0.2

0.0

0.2

0.4

0.6

0.8

1.0

1.2

1.4

1.6

1.8

2.0

Common Mode Input Voltage (V)

Input Offset Voltage (µV)

VDD = 2.7V

TA = –40°C

= +25°C

= +85°C

TA = +125°C

10%

12%

14%

16%

18%

-10-8-6-4-20246810

Input Offset Voltage Drift (µV/°C)

Percentage of Occurrences

1200 Samples

TA = –40 to +125°C

100

-50 -25 0 25 50 75 100 125

Ambient Temperature (°C)

CMRR, PSRR (dB)

PSRR

CMRR

-200

-100

100

200

300

400

500

600

700

800

-0.5

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

Common Mode Input Voltage (V)

Input Offset Voltage (µV)

VDD = 5.5V

= –40°C

= +25°C

= +85°C

TA = +125°C

MCP601/1R/2/3/4

Note: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2, VOUT ≈ VDD/2,

VL = VDD/2, RL = 100 kΩ to VL, CL = 50 pF and CS is tied low.

FIGURE 2-13: Channel-to-Channel

Separation vs. Frequency.

FIGURE 2-14: Input Bias Current, Input

Offset Current vs. Ambient Temperature.

FIGURE 2-15: DC Open-Loop Gain vs.

Load Resistance.

FIGURE 2-16: CMRR, PSRR vs.

Frequency.

FIGURE 2-17: Input Bias Current, Input

Offset Current vs. Common Mode Input Voltage.

FIGURE 2-18: DC Open-Loop Gain vs.

Supply Voltage.

100

110

120

130

140

150

1.E+03 1.E+04 1.E+05 1.E+06

Frequency (Hz)

Channel-to-Channel

Separation (dB)

No Load

Input Referred

1k 10k 100k 1M

100

1000

25 35 45 55 65 75 85 95 105 115 125

Ambient Temperature (°C)

Input Bias and Offset

Currents (pA)

VDD = 5.5V

VCM

= 4.3V

IOS

100

110

120

1.E+02 1.E+03 1.E+04 1.E+05

Load Resistance (Ω)

DC Open-Loop Gain (dB)

VDD = 2.7V

VDD = 5.5V

100 1k 10k 100k

100

1.E+00 1.E+01 1.E+02 1.E+03 1.E+04 1.E+05 1.E+06

Frequency (Hz)

CMRR, PSRR (dB)

CMRR

VDD = 5.0V

110010k1M

PSRR+

PSRR–

10 1k 100k

100

1000

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5

Common Mode Input Voltage (V)

Input Bias and Offset

Currents (pA)

IB, +85°C

VDD = 5.5V

max. VCMR ≥ 4.3V

IB, +125°C

IOS, +85°C

IOS, +125°C

100

110

120

2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5

Power Supply Voltage (V)

DC Open-Loop Gain (dB)

RL = 25 kΩ

MCP601/1R/2/3/4

Note: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2, VOUT ≈ VDD/2,

VL = VDD/2, RL = 100 kΩ to VL, CL = 50 pF and CS is tied low.

FIGURE 2-19: Gain Bandwidth Product,

Phase Margin vs. Load Resistance.

FIGURE 2-20: Output Volt age Headroom

vs. Output Current.

FIGURE 2-21: Maximum Output Voltage

Swing vs. Frequency.

FIGURE 2-22: DC Open-Loop Gain vs.

Temperature.

FIGURE 2-23: Output Voltage Headroom

vs. Temperature.

FIGURE 2-24: Output Short-Circuit Current

vs. Supply Voltage.

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

1.E+02 1.E+03 1.E+04 1.E+05

Load Resistance (Ω)

Gain Bandwidth Product

(MHz)

100

Phase Margin, G = +1 (°)

100 10k1k 100k

VDD = 5.0V

GBWP

PM, G = +1

100

1,000

0.01 0.1 1 10

Output Current Magnitude (mA)

Output Headroom (mV);

VDD – VOH and VOL – VSS

VDD – VOH

VOL – VSS

0.1

1.E+04 1.E+05 1.E+06

Frequency (Hz)

Maximum Output Voltage

Swing (V P-P)

10k 100k 1M

VDD = 5.5V

VDD = 2.7V

100

110

120

130

-50 -25 0 25 50 75 100 125

Ambient Temperature (°C)

DC Open-Loop Gain (dB)

VDD

= 5.5

VDD

= 2.7

RL = 25 kΩ

= 5 kΩ

100

1000

-50-25 0 255075100125

Ambient Temperature (°C)

Output Headroom (mV);

VDD – VOH and VOL – VSS

VDD – VOH

RL = 25 kΩ

VDD = 5.5V

RL tied to VDD/2

VOL – VSS

RL = 5 kΩ

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5

Supply Voltage (V)

Output Short Circuit Current

Magnitude (mA)

TA = –40°C

TA = +25°C

TA = +85°C

TA = +125°C

MCP601/1R/2/3/4

Note: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2, VOUT ≈ VDD/2,

VL = VDD/2, RL = 100 kΩ to VL, CL = 50 pF and CS is tied low.

FIGURE 2-25: Large Signal Non-Inverting

Pulse Response.

FIGURE 2-26: Small Signal Non-Inverting

Pulse Response.

FIGURE 2-27: Chip Select Timing

(MCP603).

FIGURE 2-28: Large Signal Inver ting Pulse

Response.

FIGURE 2-29: Small Signal Inverting Pulse

Response.

FIGURE 2-30: Quiescent Current Through

VSS vs. Chip Select Voltage (MCP603).

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

Time (1 µs/div)

Output Voltage (V)

VDD = 5.0V

G = +1

Time (1 µs/div)

Output Voltage (20 mV/div)

VDD = 5.0V

G = +1

-0.5

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

5.5

Time (5 µs/div)

Output Voltage,

Chip Select Voltage (V)

VDD = 5.0V

G = +1

VIN = 2.5V

RL = 100 kΩ to GND

VOUT Active

VOUT High-Z

0.0

0.5

1.0

1.5

2.0

2.5

3.0

3.5

4.0

4.5

5.0

Time (1 µs/div)

Output Voltage (V)

VDD = 5.0V

G = –1

Time (1 µs/div)

Output Voltage (20 mV/div)

VDD = 5.0V

G = –1

-800

-700

-600

-500

-400

-300

-200

-100

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5

Chip Select Voltage (V)

Quiescent Current

through V SS (µA)

VDD = 5.5V

MCP601/1R/2/3/4

Note: Unless otherwise indicated, TA = +25°C, VDD = +2.7V to +5.5V, VSS = GND, VCM = VDD/2, VOUT ≈ VDD/2,

VL = VDD/2, RL = 100 kΩ to VL, CL = 50 pF and CS is tied low.

FIGURE 2-31: Chip Select Pin Input

Current vs. Chip Select Voltage.

FIGURE 2-32: Hysteresis of Chip Select’s

Internal Switch.

FIGURE 2-33: The MCP601/1R/2/3/4

family of op amps shows no phase reversal

under input overdrive.

FIGURE 2-34: Measured Input Current vs.

Input Voltage (below VSS).

0.0

0.1

0.2

0.3

0.4

0.5

0.6

0.7

0.8

0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5

Chip Select Voltage (V)

Chip Select Pin Current (µA)

VDD = 5.5V

0.0

0.5

1.0

1.5

2.0

2.5

3.0

0.00.51.01.52.02.53.03.54.04.55.0

Chip Select Voltage (V)

Internal Chip Select Switch

Output Voltage (V)

VDD = 5.0V

Amplifier Hi-Z

Amplifier On

CS Hi to Low CS Low to Hi

-1

Time (5 µs/div)

Input and Output Voltages (V)

VDD = +5.0V

G = +2

VIN

VOUT

1.E-12

1.E-11

1.E-10

1.E-09

1.E-08

1.E-07

1.E-06

1.E-05

1.E-04

1.E-03

1.E-02

-1.0 -0.9 -0.8 -0.7 -0.6 -0.5 -0.4 -0.3 -0.2 -0.1 0.0

Input Voltage (V)

Input Current Magnitude (A)

+125°C

+85°C

+25°C

-40°C

10m

100µ

10µ

1µ

100n

10n

100p

10p

MCP601/1R/2/3/4

3.0 PIN DESCRIPTIONS

Description s of the pi ns are listed in Table 3-1 (single op amps) and Table 3-2 (dual and quad op amps).

TABLE 3-1: PIN FUNCTION TABLE FOR SINGLE OP AMPS

TABLE 3-2: PIN FUNCTION TABLE FOR DUAL AND QUAD OP AMPS

3.1 Analog Outputs

The op amp output pins are low-impedance voltage

sources.

3.2 Analog Inputs

The op amp non-inverting and inverting inputs are high-

impedance CMOS inputs with low bias currents.

3.3 Chip Select Digital Input

This is a CMOS, Schmitt-triggered input that places the

part into a low power mode of operation.

3.4 Power Supply Pins

The positive power supply pin (VDD) is 2.5V to 6.0V

higher than the negative power supply pin (VSS). For

normal operation, the other pins are at voltages

between VSS and VDD.

Typically, these parts are used in a single (positive)

supply configuration. In this case, VSS is connected to

ground and VDD is connected to the supply. VDD will

need bypass capacitors.

MCP601 MCP601R MCP603

Symbol Description

PDIP, SOIC,

TSSOP SOT-23-5 SOT-23-5

(Note 1) SOT-23-6 PDIP, SOIC,

TSSOP

6116 6 V

OUT Analog Output

2442 2 V

IN– Inverting Input

3333 3 V

IN+ Non-inverting Input

7527 7 V

DD Positive Power Supply

4254 4 V

SS Negative Power Supply

———8 8 CSChip Select

1, 5, 8 — — 1, 5 1 NC No Internal Connection

Note 1: The MCP601R is only available in the 5-pin SOT-23 package.

MCP602 MCP604

Symbol Description

PDIP, SOIC,

TSSOP PDIP, SOIC,

TSSOP

11 V

OUTA Analog Outpu t (op amp A)

22 V

INA– Inverting Input (op amp A)

33 V

INA+ Non-inverting Input (op amp A)

84 V

DD Positive Power Supply

55 V

INB+ Non-inverting Input (op amp B)

66 V

INB– Inverting Input (op amp B)

77 V

OUTB Analog Output (op amp B)

—8 V

OUTC Analog Output (op amp C)

—9 V

INC– Inverting Input (op amp C)

—10 V

INC+ Non-inverting Input (op amp C)

411 V

SS Negative Power Supply

—12 V

IND+ Non-inverting Input (op amp D)

—13 V

IND– Inverting Input (op amp D)

—14 V

OUTD Analog Output (op amp D)

MCP601/1R/2/3/4

4.0 APPLICATIONS INFORMATION

The MCP601/1R/2/3/4 family of op amps are fabricated

on Microchip’s state-of-the-art CMOS process. They

are unity-gain stable and suitable for a wide range of

general purpose applications.

4.1 Inputs

4.1.1 PHASE REVERSAL

The MCP601/1R/2/3/4 op amp is desig ned to prevent

phase reversal when the inpu t pins exceed the supp ly

voltages. Figure 2-34 shows the input voltage

exceeding the supply voltage without any phase

reversal.

4.1.2 INPUT VOLTAGE AND CURRENT

LIMITS

The ESD protection on the inputs can be depicted as

shown in Figure 4-1. This structure was chosen to

protect the input transistors, and to minimize input bias

current (IB). The input ESD diodes clamp the inputs

when they try to go more than one diode drop below

VSS. They also clamp any voltages that go too far

above VDD; their breakdown voltage is high enough to

allow normal operation, and low enough to bypass

quick ESD events within the specified limits.

FIGURE 4-1: Simplified Analog Input ESD

Structures.

In order to prevent damage and/or improper operation

of these op amps, the circuit they are in must li mit the

currents and voltages at the VIN+ and VIN– pins (see

Absolute Maximum Ratings † at the beginning of

Section 1.0 “Electrical Characteristics”). Figure 4-2

shows the recommended approach to protecting these

inputs. The internal ESD diodes prevent the input pins

(VIN+ and VIN–) from going too far below ground, and

the resistors R1 and R2 limit the possible current drawn

out of the input pins. Diodes D1 and D2 prevent the

input pins (VIN+ and VIN–) from going too far above

VDD, and dump any currents onto VDD. When

implemented as shown, resi stors R1 and R2 also limit

the current through D1 and D2.

FIGURE 4-2: Protecting the Analog

Inputs.

It is also possible to connect the diodes to the left of

resistors R1 and R2. In this case, current through the

diodes D1 and D2 needs to be limited by some other

mechanism. The resistors then serve as in-rush current

limiters; the DC current into the input pins (VIN+ and

VIN–) should be very small.

A significant amount of current can flow out of the

inputs when the common mode voltage (VCM) is below

ground (VSS); see Figure 2-34. Applications that are

high impedance may need to limit th e useable voltage

range.

4.1.3 NORMAL OPERATION

The Common Mode Input Voltage Range (VCMR)

includes ground in single-supply systems (VSS), but

does not include VDD. This means that the amplifier

input behaves linearly as long as the Common Mode

Input Voltage (VCM) is kept within the specified VCMR

limits (VSS–0.3V to VDD–1.2V at +25°C).

Figure 4-3 shows a unity gain buffer. Since VOUT is the

same voltage as the inverting input, VOUT must be kept

below VDD–1.2V for correct operation.

FIGURE 4-3: Unity Gain Buffer has a

Limited VOUT Range.

Bond

Pad

Bond

Pad

Bond

Pad

VDD

VIN+

VSS

Input

Stage Bond

Pad VIN–

MCP60X

VDD

R1>VSS – (minimum expected V1)

2mA

R2>VSS – (minimum expected V2)

2mA

V2R2

MCP60X VOUT

–

VIN

MCP601/1R/2/3/4

4.2 Rail-to-Rail Output

There are two specifications that describe the output

swing capability of the MCP601/1R/2/3/4 family of op

amps. The first specification (Maximum Output Voltage

Swing) defines the absolute maximum swing that can

be achieved under the specified load conditions. For

instance, the output voltage swings to within 15 mV of

the negative rail with a 25 kΩ load to VDD/2. Figure 2-33

shows how the output voltage is limited when the input

goes beyond the li near region of operation.

The second specification that describes the output

swing capability of these amplifiers is the Linear Output

V oltage Swing. This specification defines the maximum

output swing that can be achieved while the amplifier is

still operating in its linear region. To verify linear

operation in this range, the large signal (DC Open-Loop

Gain (AOL)) is measured at points 100 mV inside the

supply rails. The measurement must exceed the

specified gains in the specification table.

4.3 MCP603 Chip Select

The MCP603 is a single amplifier with Chip Select

(CS). When CS is pulled high, the supply current drops

to -0.7 µA (typ.), which is pu lled through the CS pin to

VSS. When this happens, the amplifier output is put into

a high-impedance state. Pulling CS low enables the

amplifier.

The CS pin has an internal 5 MΩ (typical) pull-down

resistor connected to VSS, so it will go low if the CS pin

is left floating. Figure 1-1 is the Chip Select timing

diagram and shows the output voltage, supply currents,

and CS current in response to a CS pulse. Figure 2-27

shows the measured output voltage response to a CS

pulse.

4.4 Capacitive Loads

Driving large capacitive loads can cause stability

problems for voltage feedback op amps. As the load

capacitance increases, the feedback loop’s phase

margin decreases and the closed-loop bandwidth is

reduced. This produce s gain peaking in the frequency

response with overshoot and ringing in the step

response.

When driving large capacitive loads with these op

amps (e.g., > 40 pF when G = +1), a small series

resistor at the output (RISO in Figure 4-4) improves the

feedback loop’s phase margin (stability) by making the

output load resistive at higher frequencies. The

bandwidth will be generally lower than the bandwidth

with no capacitive load.

FIGURE 4-4: Output resistor RISO

stabilizes large capacitive loads.

Figure 4-5 gives recommended RISO values for

different capacitive loads and gains. The x-axis is the

normalized load capacitance (CL/GN) in order to make

it easier to interpret the plot for arbitrary gains. GN is the

circuit’s noise gain. For non-inverting gains, GN and the

gain are equal. For inverting gains, GN = 1 + |Gain|

(e.g., -1 V/V gives GN = +2 V/V).

FIGURE 4-5: Recommended RISO values

for capacitive loads.

Once you have selected RISO for you r circuit, double-

check the resulting frequency response peaking and

step response overshoot in your circuit. Evalu ation on

the bench and simulations with the MCP601/1R/2/3/4

SPICE macro model are very helpful. Modify RISO’s

value until the response is reasonable.

4.5 Supply Bypass

With this family of op amps, the power supply pin (VDD

for single-supply) should have a local bypass capacitor

(i.e., 0.01 µF to 0.1 µF) within 2 mm for good high-

frequency performance. It also nee ds a bulk capacitor

(i.e., 1 µF or larger) within 100 mm to provide large,

slow currents. This bulk capacitor can be shared with

nearby analog parts.

MCP60X

RISO VOUT

–

Normalized Load Capacitance;

CL / GN (F)

Recommended RISO (Ω)

10p 100p 1n 10n

100

GN = +1

GN ≥ +2

MCP601/1R/2/3/4

4.6 Unused Op Amps

An unused op amp in a quad package (MCP604)

should be configured as shown in Figure 4-6. These

circuits prevent the output from toggling and causing

crosstalk. Circuits A sets the op amp at its minimum

noise gain. The resistor divider produces any desired

reference voltage within the output voltage range of the

op amp; the op amp buffers that reference voltage.

Circuit B uses the minimum number of components

and operates as a comparator, but it may draw more

current.

FIGURE 4-6: Unused Op Amps.

4.7 PCB Surface Leakage

In applications where low input bias current is critical,

printed circuit board (PCB) surface leakage effects

need to be considered. Surface leakage is caused by

humidity, dust or other contamination on the board.

Under low humidity conditions, a typical resistance

between nearby traces is 1012Ω. A 5V difference

would cause 5 pA of current to flow. This is greater

than the MCP601/1R/2/3/4 family’s bias current at

+25°C (1 pA, typical).

The easiest way to reduce surface leaka ge is to use a

guard ring around sensitive pins (or traces). The guard

ring is biased at the same voltage as the sensitive pin.

An example of this type of layout is shown in

Figure 4-7.

FIGURE 4-7: Example Guard Ring layout.

1. Connect the guard ring to the inverting input pin

(VIN–) for non-inverting gain amplifiers, includ-

ing unity-gain buffers. This biases the guard ring

to the common mode in p ut vol tage.

2. Connect the guard ring to the non-inverting input

pin (VIN+) for inverting gain amplifiers and

transimpedance amplifiers (converts current to

voltage, such as photo detectors). This biases

the guard ring to the same reference voltage as

the op amp (e.g., VDD/2 or ground).

4.8 Typical Applications

4.8.1 ANALOG FILTERS

Figure 4-8 and Figure 4-9 show low-pass, second-

order, Butterworth filters with a cutoff frequency of

10 Hz. The filter in Figure 4-8 has a no n-inverting ga in

of +1 V/V, and the filter in Figure 4-9 has an inverting

gain of -1 V/V.

FIGURE 4-8: Second-O rd e r, Low-Pass

Sallen-Key Filter.

FIGURE 4-9: Second-O rd e r, Low-Pass

Multiple-Feedback Filter.

The MCP601/1R/2/3/4 family of op amps have low

input bias current, which allo ws the designer to select

larger resistor val ues and smaller capacitor values for

these filters. This helps produce a compact PCB layout.

These filters, and others, can be designed using

Microchip’s Design Aids; see Section 5.2 “FilterLab®

Software” and Section 5.3 “Mindi™ Simulatior

Tool”.

VDD

¼ MCP604 (A) ¼ MCP604 (B)

VDD

VREF

VREF VDD R2

R1R2

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

⋅=

Guard Ring VIN– VIN+

C2VOUT

R1R2

VIN

47 nF

382 kΩ641 kΩ

22 nF

G = +1 V/ V

fP = 10 Hz

MCP60X

–

VOUT

R1R3C1

VIN

VDD/2

G = -1 V/V

fP = 10 Hz

618 kΩ

618 kΩ1.00 MΩ8.2 nF

47 nF MCP60X

–

MCP601/1R/2/3/4

4.8.2 INSTRUMENTATION AMPLIFIER

CIRCUITS

Instrumentation amplifiers have a di fferential input that

subtracts one input voltage from another and rejects

common mode signals. These amplifiers also provide a

single-ended output voltage.

The three-op amp instrument ation amplifier is illustrated

in Figure 4-10. One advant age of this approach is unity-

gain operation, while one disadvantage is that the

common mode input range is reduced as R2/RG gets

larger.

FIGURE 4-10: Three-Op Amp

Instrumentation Amplifier.

The two-op amp instrumentation amplifier is shown in

Figure 4-11. While its power consumption is lower than

the three-op amp version, its main drawbacks are that

the common mode range is re duced with higher gains

and it must be configured in gains of two or higher.

FIGURE 4-11: Two-Op Amp

Instrumentation Amplifier.

Both instrumentation amplifiers should use a bulk

bypass capacitor of at least 1 µF. The CMRR of these

amplifiers will be set by both the op amp CMRR and

resistor matching.

4.8.3 PHOTO DETECTION

The MCP601/1R/2/3/4 op amps can be used to easily

convert the signal from a sensor that produces an

output current (such as a photo diode) into a voltage (a

transimpedance amplifier). This i s implemented with a

single resistor (R2) in the feedback loop of the

amplifiers shown in Figure 4-12 and Figure 4-13. The

optional capacitor (C2) sometimes provides stability for

these circuits.

A photodiode configured in the Pho tovoltaic mode has

zero voltage potential placed across it (Figure 4-12). In

this mode, the light sensitivity and linearity is

maximized, making it best suited for precision

applications. The key amplifier specifications for this

application are: low input bias current, low noise,

common mode input voltage range (including g round),

and rail-to-rail output.

FIGURE 4-12: Photovoltaic Mode Detector.

In contrast, a photodiode that is configured in the

Photoconductive mode has a reverse bias voltage

across the photo-sensing element (Figure 4-13). This

decreases the diode capacitance, which facilitates

high-speed operation (e.g., high-speed digital

communications). The design trade-off is increased

diode leakage current and linearity errors. The op amp

needs to have a wide Gain Bandwidth Product

(GBWP).

FIGURE 4-13: Photoconductive Mode

Detector.

MCP60X

R3R4

VOUT

VREF

–

VOUT V1V2

–()12R2

---------+

⎝⎠

⎛⎞

------

⎝⎠

⎛⎞VREF

MCP60X

R2R2

MCP60X

VOUT

VREF

VOUT V1V2

–()1R1

------2R1

---------++

⎝⎠

⎛⎞

VREF

Light

VOUT

VDD

MCP60X

ID1

VOUT = ID1 R2

–

Light

VOUT

VDD

MCP60X

ID1

VOUT = ID1 R2

VBIAS VBIAS < 0V

–

MCP601/1R/2/3/4

5.0 DESIGN AIDS

Microchip provides the basic design tools needed for

the MCP601/1R/2/3/4 family of op amps.

5.1 SPICE Macro Model

The latest SPICE macro model for the MCP601/1R/2/

3/4 op amps is available on the Microchip web site at

www.microchip.com. This model is intended to be an

initial design tool that works well in the op amp’s linear

region of operation over the temperature range. See

the model file for information on its capabilities.

Bench testing is a very important part of any design and

cannot be replaced with simulations. Also, simulation

results using this macro model need to be validated by

comparing them to the data sheet specifications and

characteristic curves.

5.2 FilterLab® Software

Microchip’s FilterLab® software is an innovative

software tool that simplifies analog active filter (using

op amps) design. Available at no cost from the

Microchip web site at www.m icrochip.com/filterl ab, the

FilterLab d esign tool provides fu ll schematic diagrams

of the filter circuit with component values. It also

outputs the filter circuit in SPICE format, which can b e

used with the macro model to simulate actual filter

performance.

5.3 Mindi™ Simulatior Tool

Microchip’s Mindi™ simulator tool aids in the design of

various circuits useful for active filter, amplifier and

power-management applications. It is a free online

simulation tool available from the Microchip web site at

www.microchip.com/mindi. This interactive simulator

enables designers to quickly generate circuit diagrams,

simulate circuits. Circuits developed using the Mindi

simulation tool can be downloaded to a personal

computer or workstation.

5.4 MAPS (Microchip Advanced Part

Selector)

MAPS is a software tool that helps semiconductor

professionals efficiently identify Microchip devices that

fit a particular design requirement. Available at no cost

from the Microchip website at www.microchip.com/

maps, the MAPS is an overall selection tool for

Microchip’s product portfolio that includes Analog,

Memory, MCUs and DSCs. Using this tool you can

define a filter to sort features for a parametric search of

devices and export side-by-side technical comparasion

reports. Helpful links are also provided for Datasheets,

Purchase, and Sampling of Microchip parts.

5.5 Analog Demonstration and

Evaluation Boards

Microchip offers a broad spectrum of Analog

Demonstration and Evaluation Boards that are

designed to help you achieve faster time to market. For

a complete listing of these boards and their

corresponding user’s guides and technical information,

visit the Microchip web site at www.microchip.com/

analogtools.

Two of our boards that are especial ly useful are:

•P/N SOIC8EV: 8-Pin SOIC/MSOP/TSSOP/DIP

Evaluation Board

•P/N SOIC14EV: 14-Pin SOIC/TSSOP/DIP Evalu-

ation Board

5.6 Application Notes

The following Microchip Application Notes are avail-

able on the Microchip web site at www.microchip. com/

appnotes and are recommended as supplemental

reference resources.

ADN003: “Select the Right Operational Amplifier for

your Filtering Circuits”, DS21821

AN722: “Operational Amplifier Topologies and DC

Specifications”, DS00722

AN723: “Operational Amplifier AC Specifications and

Applications”, DS00723

AN884: “Driving Capacitive Loads With Op Amps”,

DS00884

AN990: “Analog Sensor Conditioning Circuits – An

Overview”, DS00990

These application notes and others are listed in the

design guide:

“Signal Chain Design Guide”, DS21825

MCP601/1R/2/3/4

6.0 PACKAGING INFORMATION

6.1 Package Marking Information

Legend: XX...X Customer-specific information

Y Year code (last digit of calendar year)

YY Year code (last 2 digits of calendar year)

WW Week code (week of January 1 is week ‘01’)

NNN Alphanumeric traceability code

Pb-free JEDEC designator for Matte Tin (Sn)

*This package is Pb-free. The Pb-free JEDEC designator ( )

can be found on the outer packaging for this package.

Note: In the event the full Microchip part number cannot be marked on one line, it will

be carried over to the next line, thus limiting the number of available

characters for customer-specific information.

5-Lead SOT-23 (MCP601 and MCP601R only)Example:

XXNN SJ25

Device I-Temp

Code

E-Temp

Code

MCP601 SANN SLNN

MCP601R SJNN SMNN

6-Lead SOT-23 (MCP603 only) Example:

XXNN AU25

Device I-Temp

Code

E-Temp

Code

MCP603 AENN AUNN

MCP601/1R/2/3/4

Package Marking Information (Continued)

XXXXXXXX

XXXXXNNN

YYWW

8-Lead PDIP (300 mil) Example:

8-Lead SOIC (150 mil) Example:

XXXXXXXX

XXXXYYWW

NNN

MCP601

I/P256

0722

MCP601

I/SN0722

256

MCP601

E/P 256

0722

MCP601E

SN 0722

256

8-Lead TSSOP Example:

XXXX

XYWW

NNN

601

I722

256

MCP601/1R/2/3/4

Package Marking Information (Continued)

14-Lead TSSOP (MCP604)Example:

XXXXXXXX

YYWW

NNN

604E

0722

256

14-Lead SOIC (150 mil) (MCP604)Example:

XXXXXXXXXX

YYWWNNN

XXXXXXXXXX MCP604ISL

0722256

MCP604

0722256

E/SL^^

14-Lead PDIP (300 mil) (MCP604)Example:

XXXXXXXXXXXXXX

YYWWNNN

MCP604-I/P

0722256

MCP604

0722256

E/P

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2YHUDOO+HLJKW $  ± 

0ROGHG3DFNDJH7KLFNQHVV $  ± 

6WDQGRII $  ± 

2YHUDOO:LGWK (  ± 

0ROGHG3DFNDJH:LGWK (  ± 

2YHUDOO/HQJWK '  ± 

)RRW/HQJWK /  ± 

)RRWSULQW /  ± 

)RRW$QJOH  ± 

/HDG7KLFNQHVV F  ± 

/HDG:LGWK E  ± 

PIN1IDBY

LASER MARK

123

A2 c

0LFURFKLS 7HFKQRORJ\ 'UDZLQJ &%

MCP601/1R/2/3/4

/HDG3ODVWLF'XDO,Q/LQH3±PLO%RG\>3',3@

1RWHV

 3LQYLVXDOLQGH[IHDWXUHPD\YDU\EXWPXVWEHORFDWHGZLWKWKHKDWFKHGDUHD

 6LJQLILFDQW&KDUDFWHULVWLF

 'LPHQVLRQV'DQG(GRQRWLQFOXGHPROGIODVKRUSURWUXVLRQV0ROGIODVKRUSURWUXVLRQVVKDOOQRWH[FHHGSHUVLGH

 'LPHQVLRQLQJDQGWROHUDQFLQJSHU$60(<0

%6&%DVLF'LPHQVLRQ7KHRUHWLFDOO\H[DFWYDOXHVKRZQZLWKRXWWROHUDQFHV

1RWH )RUWKHPRVWFXUUHQWSDFNDJHGUDZLQJVSOHDVHVHHWKH0LFURFKLS3DFNDJLQJ6SHFLILFDWLRQORFDWHGDW

KWWSZZZPLFURFKLSFRPSDFNDJLQJ

8QLWV ,1&+(6

'LPHQVLRQ/LPLWV 0,1 120 0$;

1XPEHURI3LQV 1 

3LWFK H %6&

7RSWR6HDWLQJ3ODQH $ ± ± 

0ROGHG3DFNDJH7KLFNQHVV $   

%DVHWR6HDWLQJ3ODQH $  ± ±

6KRXOGHUWR6KRXOGHU:LGWK (   

0ROGHG3DFNDJH:LGWK (   

2YHUDOO/HQJWK '   

7LSWR6HDWLQJ3ODQH /   

/HDG7KLFNQHVV F   

8SSHU/HDG:LGWK E   

/RZHU/HDG:LGWK E   

2YHUDOO5RZ6SDFLQJ H% ± ± 

NOTE 1

0LFURFKLS 7HFKQRORJ\ 'UDZLQJ &%

MCP601/1R/2/3/4

/HDG3ODVWLF6PDOO2XWOLQH61±1DUURZPP%RG\>62,&@

1RWHV

 3LQYLVXDOLQGH[IHDWXUHPD\YDU\EXWPXVWEHORFDWHGZLWKLQWKHKDWFKHGDUHD

 6LJQLILFDQW&KDUDFWHULVWLF

 'LPHQVLRQV'DQG(GRQRWLQFOXGHPROGIODVKRUSURWUXVLRQV0ROGIODVKRUSURWUXVLRQVVKDOOQRWH[FHHGPPSHUVLGH

 'LPHQVLRQLQJDQGWROHUDQFLQJSHU$60(<0

%6& %DVLF'LPHQVLRQ7KHRUHWLFDOO\H[DFWYDOXHVKRZQZLWKRXWWROHUDQFHV

5() 5HIHUHQFH'LPHQVLRQXVXDOO\ZLWKRXWWROHUDQFHIRULQIRUPDWLRQSXUSRVHVRQO\

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KWWSZZZPLFURFKLSFRPSDFNDJLQJ

8QLWV 0,//,0(7(56

'LPHQVLRQ/LPLWV 0,1 120 0$;

1XPEHURI3LQV 1 

3LWFK H %6&

2YHUDOO+HLJKW $ ± ± 

0ROGHG3DFNDJH7KLFNQHVV $  ± ±

6WDQGRII



$  ± 

2YHUDOO:LGWK ( %6&

0ROGHG3DFNDJH:LGWK ( %6&

2YHUDOO/HQJWK ' %6&

&KDPIHURSWLRQDO K  ± 

)RRW/HQJWK /  ± 

)RRWSULQW / 5()

)RRW$QJOH  ± 

/HDG7KLFNQHVV F  ± 

/HDG:LGWK E  ± 

0ROG'UDIW$QJOH7RS  ± 

0ROG'UDIW$QJOH%RWWRP  ± 

NOTE 1

12 3

0LFURFKLS 7HFKQRORJ\ 'UDZLQJ &%

MCP601/1R/2/3/4

/HDG3ODVWLF7KLQ6KULQN6PDOO2XWOLQH67±PP%RG\>76623@

1RWHV

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 'LPHQVLRQV'DQG(GRQRWLQFOXGHPROGIODVKRUSURWUXVLRQV0ROGIODVKRUSURWUXVLRQVVKDOOQRWH[FHHGPPSHUVLGH

 'LPHQVLRQLQJDQGWROHUDQFLQJSHU$60(<0

%6& %DVLF'LPHQVLRQ7KHRUHWLFDOO\H[DFWYDOXHVKRZQZLWKRXWWROHUDQFHV

5() 5HIHUHQFH'LPHQVLRQXVXDOO\ZLWKRXWWROHUDQFHIRULQIRUPDWLRQSXUSRVHVRQO\

1RWH )RUWKHPRVWFXUUHQWSDFNDJHGUDZLQJVSOHDVHVHHWKH0LFURFKLS3DFNDJLQJ6SHFLILFDWLRQORFDWHGDW

KWWSZZZPLFURFKLSFRPSDFNDJLQJ

8QLWV 0,//,0(7(56

'LPHQVLRQ/LPLWV 0,1 120 0$;

1XPEHURI3LQV 1 

3LWFK H %6&

2YHUDOO+HLJKW $ ± ± 

0ROGHG3DFNDJH7KLFNQHVV $   

6WDQGRII $  ± 

2YHUDOO:LGWK ( %6&

0ROGHG3DFNDJH:LGWK (   

0ROGHG3DFNDJH/HQJWK '   

)RRW/HQJWK /   

)RRWSULQW / 5()

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/HDG:LGWK E  ± 

NOTE 1

L1 L

0LFURFKLS 7HFKQRORJ\ 'UDZLQJ &%

MCP601/1R/2/3/4

/HDG3ODVWLF'XDO,Q/LQH3±PLO%RG\>3',3@

1RWHV

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 6LJQLILFDQW&KDUDFWHULVWLF

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 'LPHQVLRQLQJDQGWROHUDQFLQJSHU$60(<0

%6&%DVLF'LPHQVLRQ7KHRUHWLFDOO\H[DFWYDOXHVKRZQZLWKRXWWROHUDQFHV

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KWWSZZZPLFURFKLSFRPSDFNDJLQJ

8QLWV ,1&+(6

'LPHQVLRQ/LPLWV 0,1 120 0$;

1XPEHURI3LQV 1 

3LWFK H %6&

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0ROGHG3DFNDJH7KLFNQHVV $   

%DVHWR6HDWLQJ3ODQH $  ± ±

6KRXOGHUWR6KRXOGHU:LGWK (   

0ROGHG3DFNDJH:LGWK (   

2YHUDOO/HQJWK '   

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/HDG7KLFNQHVV F   

8SSHU/HDG:LGWK E   

/RZHU/HDG:LGWK E   

2YHUDOO5RZ6SDFLQJ H% ± ± 

NOTE 1

123

0LFURFKLS 7HFKQRORJ\ 'UDZLQJ &%

MCP601/1R/2/3/4

/HDG3ODVWLF6PDOO2XWOLQH6/±1DUURZPP%RG\>62,&@

1RWHV

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 6LJQLILFDQW&KDUDFWHULVWLF

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 'LPHQVLRQLQJDQGWROHUDQFLQJSHU$60(<0

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5() 5HIHUHQFH'LPHQVLRQXVXDOO\ZLWKRXWWROHUDQFHIRULQIRUPDWLRQSXUSRVHVRQO\

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8QLWV 0,//,0(7(56

'LPHQVLRQ/LPLWV 0,1 120 0$;

1XPEHURI3LQV 1 

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0ROGHG3DFNDJH7KLFNQHVV $  ± ±

6WDQGRII $  ± 

2YHUDOO:LGWK ( %6&

0ROGHG3DFNDJH:LGWK ( %6&

2YHUDOO/HQJWK ' %6&

&KDPIHURSWLRQDO K  ± 

)RRW/HQJWK /  ± 

)RRWSULQW / 5()

)RRW$QJOH  ± 

/HDG7KLFNQHVV F  ± 

/HDG:LGWK E  ± 

0ROG'UDIW$QJOH7RS  ± 

0ROG'UDIW$QJOH%RWWRP  ± 

NOTE 1

123

hα

0LFURFKLS 7HFKQRORJ\ 'UDZLQJ &%

MCP601/1R/2/3/4

/HDG3ODVWLF7KLQ6KULQN6PDOO2XWOLQH67±PP%RG\>76623@

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MCP601/1R/2/3/4

NOTES:

MCP601/1R/2/3/4

APPENDIX A: REVISION HISTORY

Revision G (December 2007)

• Updated Figure 2-15 and Figure 2-19.

• Updated Table 3-1 and Table 3-2.

• Updated notes to Section 1.0 “Electrical

Characteristics”.

• Expanded Analog Input Absolute Maximum

Voltage Range (app lies retroactively).

• Expanded operating VDD to a maximum of 6.0V.

• Added Figure 2-34.

• Added Section 4.1.1 “Phase Reversal”,

Section 4.1.2 “Input Voltage and Current Lim-

its”, and Section 4.1.3 “Normal Operation”.

• Corrected Section 6.0 “Packaging Informa-

tion”.

Revision F (February 2004)

• Undocumented changes.

Revision E (September 2003)

• Undocumented changes.

Revision D (April 2000)

• Undocumented changes.

Revision C (July 1999)

• Undocumented changes.

Revision B (June 1999)

• Undocumented changes.

Revision A (March 1999)

• Original Release of this Document.

MCP601/1R/2/3/4

NOTES:

MCP601/1R/2/3/4

PRODUCT IDENTIFICATION SYSTEM

To order or obtain information, e.g., on pr icing or delivery, refer to the factory or the listed sales office.

Device MCP601 Single Op Amp

MCP601T Single Op Amp

(Tape and Reel for SOT-23, SOIC and TSSOP)

MCP601RT Single Op Amp

(Tape and Reel for SOT-23-5)

MCP602 Dual Op Amp

MCP602T Dual Op Amp

(Tape and Reel for SOIC and TSSOP)

MCP603 Single Op Amp with Chip Select

MCP603T Single Op Amp with Chip Select

(Tape and Reel for SOT-23, SOIC and TSSOP)

MCP604 Quad Op Amp

MCP604T Q uad Op Amp

(Tape and Reel for SOIC and TSSOP)

Temperature Range I = -40°C to +85°C

E= -40°C to +125°C

Package OT = Plastic SOT-23, 5-lead (MCP601 only)

CH = Plastic SOT-23, 6-lead (MCP603 only)

P = Plastic DIP (300 mil body), 8, 14 lead

SN = Plastic SOIC (3.90 mm body), 8 lead

SL = Plastic SOIC (3.90 mm body), 14 lead

ST = Plastic TSSOP (4.4 mm body), 8, 14 l ead

PART NO. –X /XX

PackageTemperature

Range

Device

Examples:

a) MCP601-I/P: Single Op Amp,

Industrial Temperature,

8 lead PDIP package.

b) MCP601-E/SN: Single Op Amp,

Extended Temperature,

8 lead SOIC package.

c) MCP601T-E/ST: Tape and Reel,

Extended Temperature,

Single Op Amp,

8 lead TSSOP package

d) MCP601RT-I/OT:Tape and Reel,

Industrial Temperature,

Single Op Amp, Rotated

5 lead SOT-23 package.

e) MCP601RT-E/OT:Tape and Reel,

Extended Temperature,

Single Op Amp, Rotated,

5 lead SOT-23 package.

a) MCP602-I/SN: Dual Op Amp,

Industrial Temperature,

8 lead SOIC package.

b) MCP602-E/P: Dual Op Amp,

Extended Temperature,

8 lead PDIP package.

c) MCP602T-E/ST: Tape and Reel,

Extended Temperature,

Dual Op Amp,

8 lead TSSOP package.

a) MCP603-I/SN: Industrial Temperature,

Single Op Amp with Chip

Select, 8 lead SOIC package.

b) MCP603-E/P: Extended Temperature,

Single Op Amp with Chip

Select, 8 lead PDIP package.

c) MCP603T-E/ST: Tape and Reel,

Extended Temperature,

Single Op Amp with Chip

Select 8 lead TSSOP package.

d) MCP603T-I/SN: Tape and Reel,

Industrial Temperature,

Single Op Amp with Chip

Select, 8 lead SOIC package.

a) MCP604-I/P: Industrial Temperature,

Quad Op Amp,

14 lead PDIP package.

b) MCP604-E/SL: Extended Temperature,

Quad Op Amp,

14 lead SOIC package.

c) MCP604T-E/ST: Tape and Reel,

Extended Temperature,

Quad Op Amp,

14 lead TSSOP package.

MCP601/1R/2/3/4

NOTES:

Information contained in this publication regarding device

applications and the like is provided only for your convenience

and may be superseded by updates. It is your responsibility to

ensure that your application meets with your specifications.

MICROCHIP MAKES NO REPRESENTATIONS OR

WARRANTIES OF ANY KIND WHETHER EXPRESS OR

IMPLIED, WRITTEN OR ORAL, STATUTORY OR

OTHERWISE, RELATED TO THE INFORMATION,

INCLUDING BUT NOT LIMITED TO ITS CONDITION,

QUALITY, PERFORMANCE, MERCHANTABILITY OR

FITNESS FOR PURPOSE. Microchip disclaims all liability

arising from this information and its use. Use of Microchip

devices in life support and/or safety applications is entirely at

the buyer’s risk, and the buyer agrees to defen d, indemnify and

hold harmless Microchip from any and all damages, claims,

suits, or expenses resulting from such use. No licenses are

conveyed, implicitly or otherwise, under any Microchip

intellectual property rights.

Trademarks

The Microchip name and logo, the Microchip logo, Accuron,

dsPIC, KEELOQ, KEELOQ logo, microID, MPLAB, PIC,

PICmicro, PICST ART, PRO MA TE, rfPIC and SmartShunt are

registered trademarks of Microchip Technology Incorporated

in the U.S.A. and other countries.

AmpLab, FilterLab, Linear Active Thermistor, Migratable

Memory, MXDEV, MXLAB, SEEVAL, SmartSensor and The

Embedded Control Solutions Company are registered

trademarks of Microchip Technology Incorporated in the

U.S.A.

Analog-for-the-Digital Age, Application Maestro, CodeGuard,

dsPICDEM, dsPICDEM.net, dsPICworks, dsSPEAK, ECAN,

ECONOMONITOR, FanSense, FlexROM, fuzzyLAB,

In-Circuit Serial Programming, ICSP, ICEPIC, Mindi, MiWi,

MPASM, MPLAB Certified logo, MPLIB, MPLINK, PICkit,

PICDEM, PICDEM.net, PICLAB, PICtail, PowerCal,

PowerInfo, PowerMate, PowerTool, REAL ICE, rfLAB, Select

Mode, Smart Serial, SmartTel, Total Endurance, UNI/O,

WiperLock and ZENA are trademarks of Microchip

Technology Incorporated in the U.S.A. and other countries.

SQTP is a service mark of Microchip T echnology Incorporated

in the U.S.A.

All other trademarks mentioned herein are property of their

respective companies.

Printed on recycled paper.

Note the following details of the code protection feature on Microchip devices:

• Microchip products meet the specification contained in their particular Microchip Data Sheet.

• Microchip believes that its family of product s is one of the most secure families of its kind on the market today, when used in the

intended manner and under normal conditions.

• There are dishonest and possibly illegal methods used to breach the code protection feature. All of these methods, to our

knowledge, require using the Microchip products in a manner outside the operating specifications contained in Microchip’s Dat a

Sheets. Most likely, the person doing so is engaged in theft of intellectual property.

• Microchip is willing to work with the customer who is concerned about the integrity of their code.

• Neither Microchip nor any other semiconductor manufacturer can guarantee the security of their code. Code protection does not

mean that we are guaranteeing the product as “unbreakable.”

Code protection is constantly evolving. We at Microchip are committed to continuously improving the code protection featur es of our

products. Attempts to break Microchip’ s code protection feature may be a violation of the Digit al Millennium Copyright Act. If such acts

allow unauthorized access to you r software or other copyrighted work, you may have a right to sue for relief under that Act .

Microchip received ISO/TS-16949:200 2 certif ication for its worldwide

headquarters, design and wafer fabrication facilities in Chandler and

Tempe, Arizona; Gresham, Oregon and design centers in California

and India. The Company’s quality system processes and procedures

are for its PIC® MCUs and dsPIC® DSCs, KEELOQ® code hopping

devices, Serial EEPROMs, microperi pherals, nonvola tile memo ry and

analog product s. In addition, Microchip ’s quality system for th e design

and manufacture of development systems is ISO 9001:2000 certified.

AMERICAS

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10/05/07