2.7V 5.5V Single Supply CMOS Amps Specifications rated from 2.7V
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MCP601/602/603/604
2.7V 5.5V Single Supply CMOS Amps
Specifications rated from 2.7V 5.5V supplies Rail-to-rail swing output Common-mode input swing below ground 2.8MHz GBWP Unity gain stable power 325µA Chip Select capability with MCP603 Industrial temperature range (-40°C 85°C) Available single, dual quad ates with single supply voltage that 2.7V, while drawing less than 325µA quiescent current. addition, common-mode input voltage range goes 0.3V below ground, making these amplifiers ideal single supply operation. These devices appropriate low-power battery operated circuits quiescent current, Converter driver amplifiers because their wide bandwidth, anti-aliasing filters virtue their input bias current. MCP601, MCP602 MCP603 available standard 8-lead PDIP, SOIC TSSOP packages. MCP601 also available SOT23-5 package. quad MCP604 offered 14-lead PDIP, SOIC TSSOP packages. PDIP SOIC packages fully specified from -40°C +85°C with power supplies from 2.7V 5.5V.
APPLICATIONS
Portable Equipment Converter Driver Photodiode Pre-amps Analog Filters Data Acquisition Notebooks PDAs Sensor Interface
TYPICAL APPLICATION
AVAILABLE TOOLS
Spice Macromodels www.microchip.com) FilterLabSoftware www.microchip.com)
2000 Microchip Technology Inc.
MCP60X
VREF Input Bias Current Over Temperature
VOUT
DESCRIPTION
Microchip Technology Inc. MCP601/602/603/604 family power operational amplifiers offered single (MCP601), single with Chip Select feature (MCP603), dual (MCP602) quad (MCP604) configurations. These operational amplifiers amps) utilize advanced CMOS technology, which provides bias current, high speed operation, high open-loop gain rail-to-rail output swing. This product offering oper-
Rail-to-Rail Output Swing
Order Pass Filter
PACKAGES
MCP601
PDIP, SOIC, TSSOP
MCP601
SOT23-5
MCP603
PDIP, SOIC, TSSOP
MCP602
PDIP, SOIC, TSSOP
OUTA -INA +INA
MCP604
PDIP, SOIC, TSSOP
OUTA OUTD
OUTB -INA -INB +INB +INA +INB -INB OUTB
-IND +IND +INC
-INC OUTC
2000 Microchip Technology Inc.
DS21314D-page
MCP601/602/603/604
ELECTRICAL CHARACTERISTICS
Maximum Ratings*
FUNCTION TABLE
NAME +IN, +INA, +INB, +INC, +IND -IN, -INA, -INB, -INC, -IND FUNCTION Non-inverting Input Terminals Inverting Input Terminals Positive Power Supply Negative Power Supply
.7.0V inputs outputs w.r.t. -0.3V +0.3V Difference Input voltage |VDD VSS| Output Short Circuit Current .continuous Current Input .±2mA Current Output Supply Pins .±30mA Storage temperature .-65°C +150°C Ambient temp. with power applied .-55°C +125°C Soldering temperature leads seconds) +300°C Tolerance .3KV Human Body Model *Notice: Stresses above those listed under "Maximum Ratings" cause permanent damage device. This stress rating only functional operation device those other conditions above those indicated operational listings this specification implied. Exposure maximum rating conditions extended periods affect device reliability.
OUT, OUTA, OUTB, OUTC, OUTD Output Terminals Chip Select internal connection
CHARACTERISTICS
Unless otherwise indicated, limits specified +2.7V +5.5V, GND, VDD/2, 100k VDD/2, VOUT VDD/2 PARAMETERS INPUT OFFSET VOLTAGE Input Offset Voltage Over Temperature(1) Drift with Temperature Power Supply Rejection INPUT CURRENT IMPEDANCE Input Bias Current Over Temperature(2) Input Offset Bias Current Common Mode Input Impedance Differential Input Impedance COMMON MODE Common-Mode Input Range Common-Mode Rejection Ratio OPEN LOOP GAIN Open Loop Gain SYMBOL dVOS/dT PSRR ZDIFF CMRR MIN. VSS-0.3 ±2.5 1013||6 1013||3 TYP. MAX. VDD-1.2 UNITS -40°C +85°C -40°C +85°C 2.7V 5.5V CONDITIONS
µV/°C µV/V
-40°C +85°C
||pF ||pF
-0.3 3.8V VDD/2, 50mV VOUT (VDD VDD/2, 100mV VOUT (VDD 100mV) VDD/2 VDD/2 VDD/2, 100dB VDD/2, 95dB VOUT 2.5V,
Open Loop Gain
OUTPUT Level/High Level Output Swing Linear Region Maximum Output Voltage Swing
VOL, VOL, VOUT VOUT
0.015 0.045 0.050 0.100
0.020 0.060 0.050 0.100
Output Short Circuit Current POWER SUPPLY Supply Voltage Quiescent Current
Note Max. Min. specified PDIP SOIC packages only. Typical refers other packages Note Max. Min. specified PDIP, SOIC, TSSOP packages only. Typical refers packages.
DS21314D-page
2000 Microchip Technology Inc.
MCP601/602/603/604
CHARACTERISTICS
Unless otherwise indicated, limits specified +2.7V +5.5V, GND, 25°C, VDD/2, 100k VDD/2, VOUT VDD/2 PARAMETERS Gain Bandwidth Product Phase Margin Slew Rate Setting Time 0.01% SYMBOL GBWP MIN. TYP. MAX. UNITS degrees V/µs CONDITIONS 50pF, +1V/V, VOUT 3.8VSTEP, 50pF, +1V/V
NOISE Input Voltage Noise Input Voltage Noise Density Input Current Noise Density
µVP-P
0.1Hz 10Hz 1kHz 1kHz
SPECIFICATIONS MCP603 CHIP SELECT FEATURE
Unless otherwise indicated, limits specified +2.7V +5.5V, GND, 25°C, VDD/2, 100k VDD/2, VOUT VDD/2 PARAMETERS SPECIFICATIONS Logic Threshold, Input Current, Amplifier Output Leakage, High HIGH SPECIFICATIONS Logic Threshold, High Input High, Shutdown Current Input High, Shutdown Current DYNAMIC SPECIFICATIONS Amplifier Output High Turn-on Time High Amplifier Output High Threshold Hysteresis tOFF ICSH 0.51 entire range ICSL -1.0 0.42 entire range 0.2VDD SYMBOL MIN. TYP. MAX. UNITS CONDITIONS
0.2VDD high 0.8VDD, Load
TEMPERATURE SPECIFICATIONS
Unless otherwise indicated, limits specified +2.7V +5.5V, PARAMETERS TEMPERATURE RANGE Specified Temperature Range Operating Temperature Range Storage Temperature Range THERMAL PACKAGE RESISTANCE Thermal Resistance, 5L-SOT23-5 Thermal Resistance, 8L-PDIP Thermal Resistance, 8L-SOIC Thermal Resistance, 8L-TSSOP Thermal Resistance, 14L-PDIP Thermal Resistance, 14L-SOIC Thermal Resistance, 14L-TSSOP +150 SYMBOL MIN. TYP. MAX. UNITS CONDITIONS
°C/W °C/W °C/W °C/W °C/W °C/W °C/W
2000 Microchip Technology Inc.
DS21314D-page
MCP601/602/603/604
TYPICAL PERFORMANCE CURVES
Note: Unless otherwise indicated, +2.7V +5.5V, 25°C, VDD/2, VDD/2 VOUT VDD/2
Quiescent Current Amplifier (µA) Power Supply,
Open Loop Gain (dB)
Gain
-100
Phase
-150 -200
100K 1000 100000 Frequency (Hz)
-250 10000000
FIGURE 2-1: Frequency
Open Loop Gain, Phase Margin
Phase Margin (degrees)
50pF, 100k
FIGURE 2-4:
Quiescent Current Power Supply
High-to-Low Transition CL=50pF, RL=100k, VDD=5V
Quiescent Current Amplifier (µA)
Temperature (°C)
2.7V 5.5V IL=0
Slew Rate
Low-to-High Transition
Temperature (°C)
FIGURE 2-2:
Slew Rate Temperature
FIGURE 2-5:
Quiescent Current Temperature
Gain Bandwidth Product (MHz) Temperature (°C) Phase 55pF Gain Bandwidth Product
10000 Input Voltage Noise Density (nV/
Phase Margin (degrees)
1000
100k
Frequency (Hz)
FIGURE 2-3: Temperature
Gain Bandwidth Product
FIGURE 2-6: Frequency
Input
Voltage
Noise
Density
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2000 Microchip Technology Inc.
MCP601/602/603/604
Note: Unless otherwise indicated, +2.7V +5.5V, 25°C, VDD/2, VDD/2 VOUT VDD/2
Number Occuracnes -2.00 0.50 0.75 1.00 -1.50 -1.25 -1.00 -0.75 -1.75 -0.25 1.25 0.00 0.25 1.50 1.75 -0.50 2.00
5.5V 100k Sample Size
Number Occurances
5.5V 100k Sample Size Temperature Range -40°C +85°C
Offset Voltage (mV)
Change Offset Voltage with Temperature (µV/°C)
FIGURE 2-7: Offset Voltage Occurrences with 5.5V
Number Occurances 0.00 0.25
Number
FIGURE 2-10: Offset Voltage Drift Number Occurrences with 5.5V
2.7V 100k Sample Size
Number Occurances
2.7V 100k Sample Size Temperature Range -40°C +85°C
0.50
0.75
1.00
1.25
1.50
1.75
-1.75
-1.50
-1.25
-1.00
-0.75
-0.50
-2.00
-0.25
2.00
Change Offset Voltage with Temperature (µV/°C)
Offset Voltage (mV)
FIGURE 2-8: Offset Voltage Occurrences with 2.7V.
Number
FIGURE 2-11: Offset Voltage Drift Number Occurrences with 2.7V
Offset Voltage (µV) -100 -200 -300 -400 -500 5.5V 2.7V
100k
Common Mode Rejection Ratio, Power Supply Rejection Ratio (dB)
CMRR 2.7V -0.3V 1.5V PSRR, 2.7V 5.5V CMRR 5.5V -0.3V 4.3V
Temperature
Temperature (°C)
FIGURE 2-9: Normalized Offset Voltage Temperature with 2.7V
FIGURE 2-12: Common-Mode Rejection Ratio, Power Supply Rejection Ratio Temperature
2000 Microchip Technology Inc.
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MCP601/602/603/604
Note: Unless otherwise indicated, +2.7V +5.5V, 25°C, VDD/2, VDD/2 VOUT VDD/2
Offset Voltage (µV) Common Mode Voltage 2.7V 5.5V Representative Part
PSRR+
PSRR, CMRR (dB)
PSRRCMRR
VDD=5.0V, CL=50
1000
10000
100K 100000
1000000 10000000
Frequency (Hz)
FIGURE 2-13: Offset Voltage Common-Mode Voltage
FIGURE 2-16: Common-Mode Rejection Power Supply Rejection Ratio Frequency
Ratio,
Input Bias Current, Input Offset Current (pA) Input Bias Current Levels Typically less than Below 25°C Input Bias Current 5.5V
Input Bias, Input Offset Current (pA)
Common-mode Voltage Input Offset 5.5V Input Bias Current
Input Offset Current
Temperature (°C)
FIGURE 2-14: Input Bias Current, Input Offset Current Temperature
FIGURE 2-17: Input Bias Current, Input Offset Current Common Mode Input Voltage
5.5V Open Loop Gain (dB)
Open Loop Gain (dB)
2.7V
20000
40000
60000
80000
100000
Load Resistance
Power Supply Voltage,
FIGURE 2-15: Open Loop Gain Output Load
FIGURE 2-18: Open Loop Gain Power Supply
DS21314D-page
2000 Microchip Technology Inc.
MCP601/602/603/604
Note: Unless otherwise indicated, +2.7V +5.5V, GND, 25°C, VDD/2, VDD/2 VOUT VDD/2
Gain-Bandwidth Gain-Bandwidth (MHz)
Open Loop Gain (dB)
Phase Margin (degs)
5.5V, VOUT 50mV 5.45V
5.0V, Phase Margin
100000 100K
2.7V, VOUT 50mV 2.65V
1000 Resistance
10000
Temperature (°C)
FIGURE 2-19: Gain Bandwidth, Phase Margin Load Resistance
FIGURE 2-22: Open Loop Gain Temperature
VDD-VOH, VOL-VSS (mV) VDD=2.7V VDD-VOH VDD=5.5V VDD=5.5V VDD-VOH VDD=2.7V
VOL-VSS, VDD=2.7V VDD-VOH, VDD=5.5V
VOH, (mV)
VOL-VSS, VDD=5.5V
VDD-VOH, VDD=2.7V
1000
10000
100K 100000
Temperature (°C)
Load Resistance
FIGURE 2-20: Level High Level Output Swing Resistive Load
FIGURE 2-23: Level High Level Output Swing Temperature
Full-Scale Output Voltage Swing
Short Circuit Current (mA) Negative Short Circuit Current 5.5V Negative Short Circuit Current 2.7V Positive Short Circuit Current 2.7V Positive Short Circuit Current 5.5V
1000
10000
100K 100000
Frequency (Hz)
1000000
10000000
Temperature (°C)
FIGURE 2-21: Maximum Full Scale Output Voltage Swing Frequency
FIGURE 2-24: Output Temperature
Short
Circuit
Current
2000 Microchip Technology Inc.
DS21314D-page
MCP601/602/603/604
Note: Unless otherwise indicated, +2.7V +5.5V, GND, 25°C, VDD/2, VDD/2 VOUT VDD/2
CL=50pF, RL=100k,
100k 50pF +1V/V
-1V/V
mV/div
FIGURE 2-25: Large Signal Non-Inverting Signal Pulse Response
FIGURE 2-28: Large Signal Inverting Signal Pulse Response
100k mV/div
mV/div
CL=50 +1V/V
CL=50pF, RL=100k, -1V/V
FIGURE 2-26: Small Response
Signal
Non-inverting
Pulse
FIGURE 2-29: Small Signal Inverting Signal Pulse Response
Current (µA)
mV/div Amplifier Output Active
100k 50pF +1V/V VIN+ 2.5V
-100 -200 -300 -400 -500 -600 -700 -800 Voltage 5.5V
Hi-Z
µS/div
FIGURE 2-27: Chip Response Time
Select
Amplifier
Output
FIGURE 2-30: Current Voltage
DS21314D-page
2000 Microchip Technology Inc.
MCP601/602/603/604
Note: Unless otherwise indicated, +2.7V +5.5V, GND, 25°C, VDD/2, VDD/2 VOUT VDD/2
Internal Switch Output
5.5V
-0.5
Voltage
Current (uA)
Amplifier Output Active (driven)
-0.1
Input High Input High Amplifier Output Hi-Z state
Input Voltage
FIGURE 2-31: Input Current Voltage
FIGURE 2-33: hysteresis
-150 Channel Channel Isolation (dB) -145 -140 -135 -130 -125 -120 -115 -110 -105 -100
1000
10000 Frequency (Hz)
100K 100000
1000000
FIGURE 2-32: Channel Channel Separation
2000 Microchip Technology Inc.
DS21314D-page
MCP601/602/603/604
APPLICATIONS INFORMATION
MCP601/602/603/604 family operational amplifiers fabricated Microchip's state-of-the-art CMOS process. They unity gain stable suitable wide range general purpose applications. With this family operational amplifiers, power supply should by-passed with capacitor. Linear Region Maximum Output Voltage Swing MCP601/602/603/604 family specified within 50mV from positive negative rail with load 100mV from rails with load. overriding condition that defines linear region amplifier open loop gain that specified over that region. voltage output region between 50mV 50mV, open loop gain specified 100dB (min) with load. classical definition open loop gain amplifier VOUT where: open loop gain amplifier, VOUT equal (VDD 50mV) (VSS 50mV) 25k, change offset voltage with changing output voltage amplifier.
Rail-to-Rail Output Swing
There specifications that describe output swing capability MCP601/602/603/604 family operational amplifiers. first specification, Level High Level Output Voltage Swing, defines absolute maximum swing that achieved under specified loaded conditions. instance, Level Output Voltage Swing MCP601/602/603/ family specified able swing least 15mV from negative rail with load VDD/2. This output swing performance shown Figure 3-1, where output MCP601 configured gain +2V/V over driven with 40kHz triangle wave. this figure, degradation output swing linearity clearly illustrated. This degradation occurs after point which open loop gain amplifier specified before amplifier reaches maximum minimum output swing.
Input Voltage Phase Reversal
Since MCP601/602/603/604 amplifier family designed with CMOS devices, does exhibit phase inversion when input pins exceed negative supply voltage. Figure shows input voltage exceeding both supplies with resulting phase inversion.
Input Output Voltage
Input Signal
VOH, (0.1mV/div)
Time(µS) Input Signal +2V/V Output Signal
-0.1 -0.3 -0.5
G=+2V/V, VDD= Time (µs) -0.7
FIGURE 3-1: Swing
Level High Level Output
FIGURE 3-2: MCP601/602/603/604 family amps have phase reversal issues. graph, amplifier unity gain buffer configuration.
second specification that describes output swing capability these amplifiers Linear Region Maximum Output Voltage Swing. This specification defines maximum output swing that achieved while amplifier still operating linear region.
DS21314D-page
2000 Microchip Technology Inc.
MCP601/602/603/604
maximum operating common-mode voltage that applied inputs 0.3V 1.2V. contrast, absolute maximum input voltage 0.3V 0.3V. Voltages input that exceed this absolute maximum rating cause excessive current flow input pins. Current beyond ±2mA cause possible reliability problems. Applications that exceed this rating must externally limited with input resistor shown Figure 3-3.
Gain-Bandwidth (MHz)
1000 10E3 10000 100E3 100000
Gain-Bandwidth VDD=5.0V, RL=100 Phase Margin 1000000 Phase Margin (degrees)
Capacitance (pF)
FIGURE 3-4: Gain Bandwidth, Phase Margin Capacitive Load MCP60X
(Maximum expected voltage VDD) (VSS Minimum expected voltage)/ 2mA. FIGURE 3-3: inputs amplifier exceed Absolute Maximum Specifications, input resistor, should used limit current flow into that pin.
RISO MCP60X
VOUT
FIGURE 3-5: Amplifier circuits that used when driving heavy capacitive loads. amplifier required drive larger capacitive loads, circuit shown Figure used. small series resistor (RISO) output amplifier improves phase margin when driving large capacitive loads. This resistor decouples capacitive load from amplifier introducing zero transfer function. This zero adjusts phase margin approximately: tan-1 GBWP RISO where: improvement phase margin, GBWP gain bandwidth product amplifier, RISO capacitive decoupling resistor, load capacitance
Capacitive Load Stability
Driving capacitive loads cause stability problems with many higher speed amplifiers. closed loop amplifier circuit, good rule thumb design phase margin that less than 45°. This conservative theoretical value, however, phase margin lower, layout parasitics degrade phase margin further causing truly unstable circuit. system phase shift will have overshoot step response approximately 25%. buffer configuration with capacitive load most difficult configuration amplifier maintain stability. Phase versus Capacitive Load MCP60X amplifier shown Figure 3-4. this figure, seen that amplifier phase margin above 40°, while driving capacitance loads 100pF.
2000 Microchip Technology Inc.
DS21314D-page
MCP601/602/603/604
Chip Select Option MCP603
MCP603 single amplifier with Chip Select option. When pulled high supply current drops 0.7µA (typ), which pulled through VSS. this state, amplifier into high impedance state. pulling letting float, amplifier enabled. Figure shows output voltage supply current response pulse. Output Hi-Z 230µA (typ) Supply Current Current 2.0nA (typ) 0.7µA (typ) 230µA (typ) 2.0nA (typ) 0.7µA (typ) tOFF Hi-Z
Current FIGURE 3-6:
0.7µA (typ)
2nA(typ)
0.7µA (typ)
Timing Diagram Function MCP603 Amplifier
Layout Considerations
applications where input bias current critical, board surface leakage effects signal coupling from trace trace need taken into consideration. 3.5.1 SURFACE LEAKAGE Surface leakage across board consequence differing voltages between traces combined with high humidity, dust contamination board. instance, typical resistance from board trace approximately 1012 under humidity conditions. adjacent trace biased input amplifier biased near zero volts, leakage current will appear amplifier's input node. This type leakage five times room temperature input bias current (1pA, typ) MCP601/602/603/604 family amplifiers. simplest technique that used reduce effects board leakage design ring around sensitive pins traces. example this type layout shown Figure 3-7.
Guard Ring FIGURE 3-7: Example Guard Ring MCP601, A-amplifier MCP602 MCP603 Board Layout
DS21314D-page
2000 Microchip Technology Inc.
MCP601/602/603/604
Circuit examples ring implementations shown Figure 3-8. Figure 3-8A, guard ring biased common-mode voltage amplifier. This type guard ring most effective applications where common-mode voltage input stage changes, such buffers, inverting gain amplifiers instrumentation amplifiers. strategy shown Figure 3-8D, biases common-mode voltage guard ring ground. This type guard ring typically used precision photo sensing circuits. Figure 3-8A 3.5.2 SIGNAL COUPLING input pins MCP601/602/603/604 amplifiers have high impedance providing opportunity noise injection, layout issues considered. These high impedance input terminals sensitive injected currents. This occur trace from high impedance input next trace that fast changing voltages, such digital clock signal. When high impedance trace close proximity trace with these types voltage changes, charge capacitively coupled into high impedance trace.
Trace
MCP60X
(typ 0.003mm)
Figure 3-8B
thickness trace
Cross-Section
length trace distance between traces FIGURE 3-9: Capacitors built with traces allowing coupling signals from trace another. shown Figure 3-9, value capacitance between traces primarily dependent distance between traces distance that traces parallel (L). From this model, amount current generated into high impedance trace equal MCP60X
Voltage Reference (could ground)
MCP60X
Figure 3-8C
where: equals current that appears high impedance trace, equals value capacitance between traces, equals change voltage trace that switching, equals amount time that voltage change took from level next.
Figure 3-8D
MCP60X
FIGURE 3-8: Examples design Board traces minimize leakage paths high impedance input pins MCP601/602/603/604 amplifiers.
2000 Microchip Technology Inc.
DS21314D-page
MCP601/602/603/604
3.6.1
Typical Applications
ANALOG FILTERS
poles that required application. Finally, program will generate SPICE macromodel, which used spice simulations. 3.6.2 INSTRUMENTATION AMPLIFIER CIRCUITS
Examples second order pass filters shown Figure 3-10 Figure 3-11. filter Figure 3-10 configured gain +1V/V greater. filter Figure 3-11 configured inverting gains.
Sallen-Key
MCP60X
instrumentation amplifier differential input, which subtracts analog signal from another rejects common mode signals. This amplifier also provides single ended analog output signal. three instrumentation amplifier illustrated Figure 3-12 instrumentation amplifier shown Figure 3-13.
MCP60X
VOUT
VOUT
MCP60X
MCP60X
s2+s(1/R1C2+1/R2C2+1/R2C1 K/R2C1+1/R1R2C2C1)
K/(R1R2C2C1)
VOUT
FIGURE 3-10: Order Pass Sallen-Key Filter
VREF
VOUT
VOUT *Bypass Capacitor, FIGURE 3-12: instrumentation amplifier built using three operational amplifiers seven resistors.
MCP60X
VOUT
-1/R1R3C2C1 s2C2C1 sC1(1/R1 1/R2 1/R3) 1/(R2R3C2C1)
VREF
MCP60X
FIGURE 3-11: Order Multiple-Feedback Filter
Pass
MCP601/602/603/604 family operational amplifiers particularly well suited these types filters. input bias current, which typically 60pA temperature), allows designer select higher value resistors, which turn reduces capacitive values. This allows designer select surface mount capacitors, which turn produce compact layout. rail-to-rail output operation MCP601/602/ 603/604 family amplifiers make these circuits well suited single supply operation. Additionally, wide bandwidth allows pass filter design 1/10 GBWP 300kHz. These filters designed using calculations provided Figures with Microchip's interactive FilterLab software. FilterLab will calculate capacitor resistor values, well determine number
MCP60X
VOUT
VOUT VREF *Bypass Capacitor, FIGURE 3-13: instrumentation amplifier also built using operational amplifiers five resistors.
DS21314D-page
2000 Microchip Technology Inc.
MCP601/602/603/604
advantage three configuration that capable unity gain operation. disadvantage, compared instrumentation amplifier, that common mode range reduces with higher gains. configuration uses fewer amps, power consumption also low. Disadvantages this configuration that common-mode range reduces with gain must configured gains higher. 3.6.3 PHOTO DETECTION contrast, photodiode that configured photoconductive mode reverse bias voltage, which applied across photo sensing element shown Figure 3-14. width depletion region reduced when this voltage applied across photo detector, which reduces photodiode parasitic capacitance significantly. This reduced parasitic capacitance facilitates high speed operation, however, linearity offset errors optimized. design trade this action increased diode leakage current linearity errors. amplifier specification this application high speed digital communication. MCP601/602/603/604 family well suited medium speed photoconductive applications with their wide bandwidth rail-to-rail output swing.
amplifiers MCP601/602/603/604 family devices used easily convert signal from sensor that produces output current, such photodiode, into voltage. This implemented with single resistor optional capacitor feedback loop amplifier shown Figure 3-14. Photodiode Photovoltaic Mode
MCP60X
Light
VOUT
Photodiode Photoconductive Mode VBIAS Light
MCP60X
VOUT
VOUT FIGURE 3-14: Photo Sensing Circuits Using MCP60X Amplifier photodiode that configured photovoltaic mode voltage potential placed across element zero biased (Figure 3-14). this mode, light sensitivity linearity maximized making best suited precision applications. amplifier specifications this application input bias current, noise rail-to-tail output swing. MCP601/602/603/604 family capable meeting three these difficult requirements.
2000 Microchip Technology Inc.
DS21314D-page
MCP601/602/603/604
SPICE MACROMODEL
Spice macromodel MCP601, MCP602, MCP603 MCP604 simulates typical amplifier performance offset voltage, power supply rejection, input capacitance, common mode rejection ratio, open loop gain over frequency, phase margin with capacitive load, output swing, power supply current, power supply current change with supply voltage, input common mode range input voltage noise. characteristics MCP601, MCP602, MCP603, MCP604 amplifiers similar terms performance behavior. This single macromodel supports four devices with exception chip select function MCP603, which modeled. listing this macromodel shown next page. most recent revision model downloaded from Microchip's site www.microchip.com.
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MCP601/602/603/604
.subckt mcp601 Output Negative supply Positive Supply Inverting input Non-inverting input Macromodel MCP601 (single), MCP602 (dual), MCP603 (single w/CS), MCP604 (quad) characteristics MCP601, MCP602, MCP603, MCP604 have same fundamental performance behavior. Consequently, this single macromodel supports four devices. However, chip select function MCP603 modeled. Revision History: 6-30-99 created 7-10-99 corrected 11-30-99 Placed ".subckt" command first line, added Ptype model listing This macromodel models typical amplifier offset voltage, power supply rejection, input capacitance, common mode rejection ratio, open loop gain over frequency, phase margin with capacitive load, output swing, power supply current, input voltage noise. NOTICE: INFORMATION PROVIDED HEREIN BELIEVED RELIABLE, HOWEVER, MICROCHIP ASSUMES RESPONSIBILITY INACCURACIES OMISSIONS. MICROCHIP ASSUMES RESPONSIBILITY THIS INFORMATION, SUCH INFORMATION SHALL ENTIRELY USER'S RISK. INTELLECTURAL PROPERTY RIGHTS LICENSES TECNOLOGY DESCRIBED HEREIN IMPLIED GRANTED THIRD PARTY. MICROCHIP RESERVES RIGHT CHANGE THIS MODEL TIME WITHOUT NOTICE. *Input Stage, pole 5MHz Ptype W=275 Ptype W=275 CDIFF 3E-12 CCM1 6E-12 CCM2 6E-12 30e-6 1.485e3 1.485e3 10.71e-12 *Input Stage Common-Mode Clampling VCMM 0.35 DCMP VCMP GCMP2 POLY(2) -0.5E-3 0.5E-3
*Input errors (vos, psr, cmr) POLY(3) (67,4) (1,34) 40e-6 3.2e-6 *Second Stage, pole 3.3Hz 0.397e9 122.8e-12
5.7e-3
2000 Microchip Technology Inc.
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MCP601/602/603/604
VSOP VSOM DSOP DSOM *HCM 4.784 -3.48 VCMP
POLY(11) VO10 VMID1 VSOP VSOM 200E-6 *mid-supply reference, output swing limit RMID1 61.62E3 VMID1 RMID2 61.62E3 ELEVEL *output RO10 VO10 input stage
10E-3 10E-3 10E-3 10E-3
voltage noise 13E3
.model Ptype PMOS .model D(IS=1e-15 =50) .model D(IS=1e-18 AF=0.6 KF=10e-17) .ENDS
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2000 Microchip Technology Inc.
MCP601/602/603/604
MCP60X PRODUCT IDENTIFICATION SYSTEM
order obtain information, e.g., pricing delivery, refer factory listed sales office. MCP60X
Plastic (300 Body), 8-lead 14-lead Plastic SOIC (150 Body), 8-lead Plastic SOIC (150 Body), 14-lead Plastic TSSOP, 8-lead 14-lead Plastic SOT23, 5-lead
Package:
Temperature Range:
-40°C +85°C
Device:
MCP601 MCP601T MCP602 MCP602T MCP603 MCP603T
Single Operational Amplifier Single Operational Amplifier (Tape Reel-SOIC/TSSOP/SOT23-5) Dual Operational Amplifier Dual Operational Amplifier (Tape Reel-SOIC/TSSOP) Single Operational Amplifier w/CS Function Single Operational Amplifier w/CS Function (Tape Reel-SOIC/TSSOP) MCP604 Quad Operational Amplifier MCP604T Quad Operational Amplifier (Tape Reel-SOIC/TSSOP)
Sales Support
Data Sheets Products supported preliminary Data Sheet have errata sheet describing minor operational differences recommended workarounds. determine errata sheet exists particular device, please contact following: Your local Microchip sales office Microchip Corporate Literature Center U.S. FAX: (480) 786-7277 Microchip Worldwide Site (www.microchip.com)
Please specify which device, revision silicon Data Sheet (include Literature using. Customer Notification System Register site (www.microchip.com/cn) receive most current information products.
2000 Microchip Technology Inc.
DS21314D-page
Note following details code protection feature PICmicro® MCUs. PICmicro family meets specifications contained Microchip Data Sheet. Microchip believes that family PICmicro microcontrollers most secure products kind market today, when used intended manner under normal conditions. There dishonest possibly illegal methods used breach code protection feature. these methods, knowledge, require using PICmicro microcontroller manner outside operating specifications contained data sheet. person doing engaged theft intellectual property. Microchip willing work with customer concerned about integrity their code. Neither Microchip other semiconductor manufacturer guarantee security their code. Code protection does mean that guaranteeing product "unbreakable". Code protection constantly evolving. Microchip committed continuously improving code protection features product.
have further questions about this matter, please contact local sales office nearest you.
Information contained this publication regarding device applications like intended through suggestion only superseded updates. your responsibility ensure that your application meets with your specifications. representation warranty given liability assumed Microchip Technology Incorporated with respect accuracy such information, infringement patents other intellectual property rights arising from such otherwise. Microchip's products critical components life support systems authorized except with express written approval Microchip. licenses conveyed, implicitly otherwise, under intellectual property rights.
Trademarks Microchip name logo, Microchip logo, FilterLab, KEELOQ, microID, MPLAB, PIC, PICmicro, PICMASTER, PICSTART, MATE, SEEVAL Embedded Control Solutions Company registered trademarks Microchip Technology Incorporated U.S.A. other countries. dsPIC, ECONOMONITOR, FanSense, FlexROM, fuzzyLAB, In-Circuit Serial Programming, ICSP, ICEPIC, microPort, Migratable Memory, MPASM, MPLIB, MPLINK, MPSIM, MXDEV, PICC, PICDEM, PICDEM.net, rfPIC, Select Mode Total Endurance trademarks Microchip Technology Incorporated U.S.A. Serialized Quick Turn Programming (SQTP) service mark Microchip Technology Incorporated U.S.A. other trademarks mentioned herein property their respective companies. 2002, Microchip Technology Incorporated, Printed U.S.A., Rights Reserved.
Printed recycled paper.
Microchip received QS-9000 quality system certification worldwide headquarters, design wafer fabrication facilities Chandler Tempe, Arizona July 1999. Company's quality system processes procedures QS-9000 compliant PICmicro® 8-bit MCUs, KEELOQ® code hopping devices, Serial EEPROMs microperipheral products. addition, Microchip's quality system design manufacture development systems 9001 certified.
2002 Microchip Technology Inc.
WORLDWIDE SALES SERVICE
AMERICAS
Corporate Office
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EUROPE
Denmark
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China Shenzhen
Microchip Technology Consulting (Shanghai) Co., Ltd., Shenzhen Liaison Office 1315, 13/F, Shenzhen Kerry Centre, Renminnan Shenzhen 518001, China Tel: 86-755-2350361 Fax: 86-755-2366086
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Microchip Technology Hongkong Ltd. Unit 901-6, Tower Metroplaza Hing Fong Road Kwai Fong, N.T., Hong Kong Tel: 852-2401-1200 Fax: 852-2401-3431
Italy
Microchip Technology Centro Direzionale Colleoni Palazzo Taurus Colleoni 20041 Agrate Brianza Milan, Italy Tel: 39-039-65791-1 Fax: 39-039-6899883
Toronto
6285 Northam Drive, Suite Mississauga, Ontario 1X5, Canada Tel: 905-673-0699 Fax: 905-673-6509
India
Microchip Technology Inc. India Liaison Office Divyasree Chambers Floor, Wing (A3/A4) O'Shaugnessey Road Bangalore, 025, India Tel: 91-80-2290061 Fax: 91-80-2290062
United Kingdom
Arizona Microchip Technology Ltd. Eskdale Road Winnersh Triangle Wokingham Berkshire, England RG41 Tel: 5869 Fax: 44-118 921-5820
01/18/02
2002 Microchip Technology Inc.
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