Datasheet MCP6N11 (Microchip) - 10

制造商Microchip
描述500 kHz, 800 µA Instrumentation Amplifier
页数 / 页50 / 10 — MCP6N11. 1.5. Explanation of DC Error Specs. EQUATION 1-6:. Section 1.4.1 …
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MCP6N11. 1.5. Explanation of DC Error Specs. EQUATION 1-6:. Section 1.4.1 “Input Offset Test. Circuit”. EQUATION 1-4:. EQUATION 1-7:

MCP6N11 1.5 Explanation of DC Error Specs EQUATION 1-6: Section 1.4.1 “Input Offset Test Circuit” EQUATION 1-4: EQUATION 1-7:

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MCP6N11 1.5 Explanation of DC Error Specs
Based on the measured VE data, we obtain the following linear fit: 1.5.1 INPUT OFFSET RELATED ERRORS The input offset error (V
EQUATION 1-6:
E) is extracted from input offset measurements (see
Section 1.4.1 “Input Offset Test
V – V ⁄ 2
Circuit”
), based on Equation 1-1: CM DD V = V + ------------------ E_LIN OS CMRR Where:
EQUATION 1-4:
V = V OS 2 V – V V – V M REF 1 3 1 V = ----------------- --------- = --------------- E G (1 + g ) CMRR V – V DM E IV H IVL VE has several terms, which assume a linear response The remaining error (ΔVE) is described by the Common to changes in VDD, VSS, VCM, VOUT and TA (all of which Mode Non-Linearity spec: are in their specified ranges):
EQUATION 1-7: EQUATION 1-5:
max ΔVE Δ INL = --------------- V – ΔV ΔV ΔV CM DD SS CM REF V – V V = V + ----------------- + --------- + --------- IVH IV L E OS PSRR CMRR CMRR Where: ΔV ΔV ΔV = V – V OUT OS E E E_LIN + --------- + ΔT ⋅ ------- A A ΔT OL A Where: The same common mode behavior applies to VE when VREF is swept, instead of VCM, since both input stages PSRR, CMRR and A are in units of V/V OL are designed the same: ΔT is in units of °C A V = 0
EQUATION 1-8:
DM V – V ⁄ 2 Equation 1-2 shows how V REF DD E affects VOUT. V = V + ------------------- E_LIN OS CMRR 1.5.2 INPUT OFFSET COMMON MODE max ΔVE INL = --------------- NON-LINEARITY CM V – V IVH IVL The input offset error (VE) changes non-linearly with VCM. Figure 1-8 shows VE vs. VCM, as well as a linear 1.5.3 DIFFERENTIAL GAIN ERROR AND fit line (VE_LIN) based on VOS and CMRR. The op amp NON-LINEARITY is in standard conditions (ΔVOUT = 0, VDM = 0, etc.). V The differential errors are extracted from differential CM is swept from VIVL to VIVH. The test circuit is in
Section 1.4.1 “Input Offset Test Circuit”
and V gain measurements (see
Section 1.4.2 “Differential
E is calculated using Equation 1-4.
Gain Test Circuit”
), based on Equation 1-2. These errors are the differential gain error (gE) and the input offset error (VE, which changes non-linearly with VDM): VE, VE_LIN (V) VE_LIN
EQUATION 1-9:
V3 VE G = 1 + R ⁄ R DM F G V2 V = G (1 + g )(V + V ) M DM E DM E These errors are adjusted for the expected output, then referred back to the input, giving the differential input error (V V ED) as a function of VDM: 1 ΔVE VCM (V)
EQUATION 1-10:
VIVL V V DD/2 IVH VM V = ------ – V
FIGURE 1-8:
Input Offset Error vs. ED G DM DM Common Mode Input Voltage. DS25073A-page 10 © 2011 Microchip Technology Inc. Document Outline 500 kHz, 800 µA Instrumentation Amplifier TABLE 1: Key Differentiating Specifications 1.0 Electrical Characteristics 1.1 Absolute Maximum Ratings † 1.2 Specifications TABLE 1-1: DC Electrical Specifications TABLE 1-2: AC Electrical Specifications TABLE 1-3: Digital Electrical Specifications TABLE 1-4: Temperature Specifications 1.3 Timing Diagrams FIGURE 1-1: Common Mode Input Overdrive Recovery Timing Diagram. FIGURE 1-2: Differential Mode Input Overdrive Recovery Timing Diagram. FIGURE 1-3: Output Overdrive Recovery Timing Diagram. FIGURE 1-4: POR Timing Diagram. FIGURE 1-5: EN/CAL Timing Diagram. 1.4 DC Test Circuits FIGURE 1-6: Test Circuit for Common Mode (Input Offset). TABLE 1-5: Selecting RF and RG FIGURE 1-7: Test Circuit for Differential Mode. TABLE 1-6: Selecting RF and RG 1.5 Explanation of DC Error Specs FIGURE 1-8: Input Offset Error vs. Common Mode Input Voltage. FIGURE 1-9: Differential Input Error vs. Differential Input Voltage. 2.0 Typical Performance Curves 2.1 DC Voltages and Currents FIGURE 2-1: Normalized Input Offset Voltage, with GMIN = 1 to 10. FIGURE 2-2: Normalized Input Offset Voltage, with GMIN = 100. FIGURE 2-3: Normalized Input Offset Voltage Drift, with GMIN = 1 to 10. FIGURE 2-4: Normalized Input Offset Voltage Drift, with GMIN = 100. FIGURE 2-5: Normalized Input Offset Voltage vs. Power Supply Voltage, with VCM = 0V and GMIN = 1 to 10. FIGURE 2-6: Normalized Input Offset Voltage vs. Power Supply Voltage, with VCM = 0V and GMIN = 100. FIGURE 2-7: Normalized Input Offset Voltage vs. Power Supply Voltage, with VCM = VDD and GMIN = 1 to 10. FIGURE 2-8: Normalized Input Offset Voltage vs. Power Supply Voltage, with VCM = VDD and GMIN = 100. FIGURE 2-9: Normalized Input Offset Voltage vs. Output Voltage, with GMIN = 1 to 10. FIGURE 2-10: Normalized Input Offset Voltage vs. Output Voltage, with GMIN = 100. FIGURE 2-11: Input Common Mode Voltage Headroom vs. Ambient Temperature. FIGURE 2-12: Normalized Input Offset Voltage vs. Common Mode Voltage, with VDD = 1.8V and GMIN = 1 to 10. FIGURE 2-13: Normalized Input Offset Voltage vs. Common Mode Voltage, with VDD = 1.8V and GMIN = 100. FIGURE 2-14: Normalized Input Offset Voltage vs. Common Mode Voltage, with VDD = 5.5V and GMIN = 1 to 10. FIGURE 2-15: Normalized Input Offset Voltage vs. Common Mode Voltage, with VDD = 5.5V and GMIN = 100. FIGURE 2-16: Normalized CMRR and PSRR vs. Ambient Temperature. FIGURE 2-17: Normalized DC Open-Loop Gain vs. Ambient Temperature. FIGURE 2-18: The MCP6N11 Shows No Phase Reversal vs. Common Mode Voltage. FIGURE 2-19: Normalized Differential Mode Voltage Range vs. Ambient Temperature. FIGURE 2-20: Normalized Differential Input Error vs. Differential Voltage, with GMIN = 1. FIGURE 2-21: Normalized Differential Input Error vs. Differential Voltage, with GMIN = 2 to 100. FIGURE 2-22: The MCP6N11 Shows No Phase Reversal vs. Differential Voltage, with VDD = 5.5V. FIGURE 2-23: Input Bias and Offset Currents vs. Ambient Temperature, with VDD = +5.5V. FIGURE 2-24: Input Bias Current vs. Input Voltage (below VSS). FIGURE 2-25: Input Bias and Offset Currents vs. Common Mode Input Voltage, with TA = +85°C. FIGURE 2-26: Input Bias and Offset Currents vs. Common Mode Input Voltage, with TA = +125°C. FIGURE 2-27: Output Voltage Headroom vs. Output Current. FIGURE 2-28: Output Voltage Headroom vs. Ambient Temperature. FIGURE 2-29: Output Short Circuit Current vs. Power Supply Voltage. FIGURE 2-30: Supply Current vs. Power Supply Voltage. FIGURE 2-31: Supply Current vs. Common Mode Input Voltage. 2.2 Frequency Response FIGURE 2-32: CMRR vs. Frequency. FIGURE 2-33: PSRR vs. Frequency. FIGURE 2-34: Normalized Open-Loop Gain vs. Frequency. FIGURE 2-35: Normalized Gain Bandwidth Product and Phase Margin vs. Ambient Temperature. FIGURE 2-36: Closed-Loop Output Impedance vs. Frequency. FIGURE 2-37: Gain Peaking vs. Normalized Capacitive Load. 2.3 Noise FIGURE 2-38: Normalized Input Noise Voltage Density vs. Frequency. FIGURE 2-39: Normalized Input Noise Voltage Density vs. Input Common Mode Voltage, with f = 100 Hz. FIGURE 2-40: Normalized Input Noise Voltage Density vs. Input Common Mode Voltage, with f = 10 kHz. FIGURE 2-41: Normalized Input Noise Voltage vs. Time, with GMIN = 1 to 10. FIGURE 2-42: Normalized Input Noise Voltage vs. Time, with GMIN = 100. 2.4 Time Response FIGURE 2-43: Small Signal Step Response. FIGURE 2-44: Large Signal Step Response. FIGURE 2-45: Slew Rate vs. Ambient Temperature. FIGURE 2-46: Maximum Output Voltage Swing vs. Frequency. FIGURE 2-47: Common Mode Input Overdrive Recovery Time vs. Normalized Gain. FIGURE 2-48: Differential Input Overdrive Recovery Time vs. Normalized Gain. FIGURE 2-49: Output Overdrive Recovery Time vs. Normalized Gain. FIGURE 2-50: The MCP6N11 Shows No Phase Reversal vs. Common Mode Input Overdrive, with VDD = 5.5V. FIGURE 2-51: The MCP6N11 Shows No Phase Reversal vs. Differential Input Overdrive, with VDD = 5.5V. 2.5 Enable/Calibration and POR Responses FIGURE 2-52: EN/CAL and Output Voltage vs. Time, with VDD = 1.8V. FIGURE 2-53: EN/CAL and Output Voltage vs. Time, with VDD = 5.5V FIGURE 2-54: EN/CAL Hysteresis vs. Ambient Temperature. FIGURE 2-55: EN/CAL Turn On Time vs. Ambient Temperature. FIGURE 2-56: Power Supply On and Off and Output Voltage vs. Time. FIGURE 2-57: POR Trip Voltages and Hysteresis vs. Temperature. FIGURE 2-58: Quiescent Current in Shutdown vs. Power Supply Voltage. FIGURE 2-59: Output Leakage Current vs. Output Voltage. 3.0 Pin Descriptions TABLE 3-1: Pin Function Table 3.1 Analog Signal Inputs 3.2 Analog Feedback Input 3.3 Analog Reference Input 3.4 Analog Output 3.5 Power Supply Pins 3.6 Digital Enable and VOS Calibration Input 3.7 Exposed Thermal Pad (EP) 4.0 Applications 4.1 Basic Performance FIGURE 4-1: Standard Circuit. FIGURE 4-2: MCP6N11 Block Diagram. FIGURE 4-3: DC Bias Resistors. 4.2 Functional Blocks FIGURE 4-4: Simplified Analog Input ESD Structures. FIGURE 4-5: Protecting the Analog Inputs Against High Voltages. FIGURE 4-6: Protecting the Analog Inputs Against High Currents. FIGURE 4-7: Input Voltage Ranges. 4.3 Applications Tips FIGURE 4-8: Output Resistor, RISO stabilizes large capacitive loads. FIGURE 4-9: Recommended RISO Values for Capacitive Loads. FIGURE 4-10: Simple Gain Circuit with Parasitic Capacitances. 4.4 Typical Applications FIGURE 4-11: Difference Amplifier. FIGURE 4-12: Difference Amplifier with Very Large Common Mode Component. FIGURE 4-13: High Side Current Detector. FIGURE 4-14: Wheatstone Bridge Amplifier. 5.0 Design Aids 5.1 Microchip Advanced Part Selector (MAPS) 5.2 Analog Demonstration Board 5.3 Application Notes 6.0 Packaging Information 6.1 Package Marking Information Appendix A: Revision History Revision A (October 2011) Product Identification System Trademarks Worldwide Sales and Service