Datasheet MCP1502 (Microchip) - 3
| 制造商 | Microchip |
| 描述 | High-Precision Buffered Voltage Reference |
| 页数 / 页 | 28 / 3 — MCP1502. 1.0. PIN FUNCTION TABLE. TABLE 1-1:. SOT-23. Symbol. Function. … |
| 文件格式/大小 | PDF / 19.5 Mb |
| 文件语言 | 英语 |
MCP1502. 1.0. PIN FUNCTION TABLE. TABLE 1-1:. SOT-23. Symbol. Function. 1.1. Buffered VREF Output (OUT). 1.4. Power Supply Input (VDD)
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MCP1502 1.0 PIN FUNCTION TABLE
The pin functions are described in Table 1-1.
TABLE 1-1: PIN FUNCTION TABLE SOT-23 Symbol Function
1 OUT VREF Output 2, 3, 5 GND System Ground 4 SHDN Shutdown Pin Active-Low 6 VDD Power Supply Input
1.1 Buffered VREF Output (OUT) 1.4 Power Supply Input (VDD)
This is the buffered reference output. The output driver This power pin also serves as the input voltage for the is tri-stated when in shutdown. voltage reference. Refer to
Section 2.0 “Electrical Characteristics”
to determine minimum voltage
1.2 System Ground (GND)
based on the device. It is recommended to connect a 0.1 µF capacitor very close to the VDD pin. This is the power supply return and should be connected to system ground.
1.3 Shutdown Pin (SHDN)
This is a digital input that wil place the device in shutdown. The device should be allowed to power up before using this feature. This pin is active-low. When this pin is low, there wil be no output.
Note:
Before using the Shutdown pin, the device should first be powered up. Once the device is fully powered up, the Shutdown pin can be used. 2021 Microchip Technology Inc. and its subsidiaries DS20006593A-page 3 Document Outline Features Applications Related Parts General Description Package Types Block Diagram 1.0 Pin Function Table TABLE 1-1: Pin Function Table 1.1 Buffered VREF Output (OUT) 1.2 System Ground (GND) 1.3 Shutdown Pin (SHDN) 1.4 Power Supply Input (VDD) 2.0 Electrical Characteristics Absolute Maximum Ratings(†) TABLE 2-1: DC Characteristics TABLE 2-2: Temperature Specifications 2.1 Terminology 2.1.1 Output Voltage (VOUT) 2.1.2 Input Voltage (VIN) 2.1.3 Temperature Coefficient (Tc) EQUATION 2-1: TC Calculation 2.1.4 Dropout Voltage (VDO) 2.1.5 Line Regulation EQUATION 2-2: EQUATION 2-3: EQUATION 2-4: EQUATION 2-5: EQUATION 2-6: 2.1.6 Load Regulation EQUATION 2-7: EQUATION 2-8: EQUATION 2-9: EQUATION 2-10: EQUATION 2-11: 2.1.7 Power Supply Rejection Ratio (PSRR) 2.1.8 Long-Term Drift 2.1.9 Output Voltage Hysteresis 2.1.10 Layout Consideration for Load Regulation 3.0 Typical Operating Curves FIGURE 3-1: MCP1502-10 VREF Output vs. Temperature, VDD = 5.5V. FIGURE 3-2: MCP1502-20 VREF Output vs. Temperature, VDD = 5.5V. FIGURE 3-3: MCP1502-40 VREF Output vs. Temperature, VDD = 5.5V. FIGURE 3-4: Load Regulation vs. Temperature. FIGURE 3-5: IDD vs. Temperature. FIGURE 3-6: MCP1502 – Line Regulation vs. Temperature. FIGURE 3-7: IDD vs. VDD for All Options. FIGURE 3-8: Noise vs. Frequency, No Load, TA = +25°C. FIGURE 3-9: PSRR vs. Frequency, No Load, TA = +25°C. FIGURE 3-10: PSRR vs. Frequency, 1 kΩ Load, TA = +25°C. FIGURE 3-11: Dropout Voltage vs. Load, TA = +25°C. FIGURE 3-12: MCP1502 Tempco Distribution, No Load, VDD = 2.7V. FIGURE 3-13: MCP1502 Tempco Distribution, No Load, VDD = 5.5V. FIGURE 3-14: VOUT Drift vs. Time, TA = +25°C, No Load, 800 Units. FIGURE 3-15: MCP1502-10 VREF and Load Regulation vs. Load Current. FIGURE 3-16: MCP1502-20 VREF and Load Regulation vs. Load Current. FIGURE 3-17: MCP1502-40 VREF and Load Regulation vs. Load Current. FIGURE 3-18: MCP1502 Output Voltage Histogram, VDD = 2.7V. FIGURE 3-19: MCP1502 Output Voltage Histogram, VDD = 5.5V. FIGURE 3-20: Fast Ramp Start-up @ +25°C for All Options. FIGURE 3-21: Slow Ramp Start-up @ +25°C for All Options. FIGURE 3-22: IDD Turn-On Transient Response. FIGURE 3-23: Shutdown Low-to-High Slow Ramp Turn-On Transient Response @ +25°C for All Options. FIGURE 3-24: Load Regulation Transient Response @ +25°C for All Options. FIGURE 3-25: Line Regulation Transient Response @ +25°C for All Options. FIGURE 3-26: MCP1502-10 Transient Response vs. Capacitive Load, VDD = 5V. FIGURE 3-27: MCP1502-20 Transient Response vs. Capacitive Load, VDD = 5V. FIGURE 3-28: MCP1502-40 Transient Response vs. Capacitive Load, VDD = 5V. FIGURE 3-29: MCP1502-10 Transient Response vs. RS, VDD = 5V, CL = 4.7 nF. FIGURE 3-30: MCP1502-20 Transient Response vs. RS, VDD = 5V, CL = 4.7 nF. FIGURE 3-31: MCP1502-40 Transient Response vs. RS, VDD = 5V, CL = 4.7 nF. FIGURE 3-32: MCP1502-10 Transient Response vs. VDD, CL = 4.7 nF. FIGURE 3-33: MCP1502-20 Transient Response vs. VDD, CL = 4.7 nF. FIGURE 3-34: MCP1502-40 Transient Response vs. VDD, CL = 4.7 nF. 4.0 Theory of Operation 5.0 Application Circuits 5.1 Application Tips 5.1.1 Basic Application Circuit FIGURE 5-1: Basic Circuit Configuration. FIGURE 5-2: Output Noise Reducing Filter. EQUATION 5-1: 5.1.2 Load Capacitor 5.1.3 Printed Circuit Board Layout Considerations 5.2 Typical Applications Circuits 5.2.1 Negative Voltage Reference FIGURE 5-3: Negative Voltage Reference. 5.2.2 A/D Converter Reference FIGURE 5-4: ADC Example Circuit. FIGURE 5-5: SAR ADC Example Circuit. 6.0 Package Information 6.1 Package Markings Appendix A: Revision History Revision A (September 2021) Product Identification System Worldwide Sales and Service
MCP1502 1.0 PIN FUNCTION TABLE
The pin functions are described in Table 1-1.
TABLE 1-1: PIN FUNCTION TABLE SOT-23 Symbol Function
1 OUT VREF Output 2, 3, 5 GND System Ground 4 SHDN Shutdown Pin Active-Low 6 VDD Power Supply Input
1.1 Buffered VREF Output (OUT) 1.4 Power Supply Input (VDD)
This is the buffered reference output. The output driver This power pin also serves as the input voltage for the is tri-stated when in shutdown. voltage reference. Refer to
Section 2.0 “Electrical Characteristics”
to determine minimum voltage
1.2 System Ground (GND)
based on the device. It is recommended to connect a 0.1 µF capacitor very close to the VDD pin. This is the power supply return and should be connected to system ground.
1.3 Shutdown Pin (SHDN)
This is a digital input that wil place the device in shutdown. The device should be allowed to power up before using this feature. This pin is active-low. When this pin is low, there wil be no output.
Note:
Before using the Shutdown pin, the device should first be powered up. Once the device is fully powered up, the Shutdown pin can be used. 2021 Microchip Technology Inc. and its subsidiaries DS20006593A-page 3 Document Outline Features Applications Related Parts General Description Package Types Block Diagram 1.0 Pin Function Table TABLE 1-1: Pin Function Table 1.1 Buffered VREF Output (OUT) 1.2 System Ground (GND) 1.3 Shutdown Pin (SHDN) 1.4 Power Supply Input (VDD) 2.0 Electrical Characteristics Absolute Maximum Ratings(†) TABLE 2-1: DC Characteristics TABLE 2-2: Temperature Specifications 2.1 Terminology 2.1.1 Output Voltage (VOUT) 2.1.2 Input Voltage (VIN) 2.1.3 Temperature Coefficient (Tc) EQUATION 2-1: TC Calculation 2.1.4 Dropout Voltage (VDO) 2.1.5 Line Regulation EQUATION 2-2: EQUATION 2-3: EQUATION 2-4: EQUATION 2-5: EQUATION 2-6: 2.1.6 Load Regulation EQUATION 2-7: EQUATION 2-8: EQUATION 2-9: EQUATION 2-10: EQUATION 2-11: 2.1.7 Power Supply Rejection Ratio (PSRR) 2.1.8 Long-Term Drift 2.1.9 Output Voltage Hysteresis 2.1.10 Layout Consideration for Load Regulation 3.0 Typical Operating Curves FIGURE 3-1: MCP1502-10 VREF Output vs. Temperature, VDD = 5.5V. FIGURE 3-2: MCP1502-20 VREF Output vs. Temperature, VDD = 5.5V. FIGURE 3-3: MCP1502-40 VREF Output vs. Temperature, VDD = 5.5V. FIGURE 3-4: Load Regulation vs. Temperature. FIGURE 3-5: IDD vs. Temperature. FIGURE 3-6: MCP1502 – Line Regulation vs. Temperature. FIGURE 3-7: IDD vs. VDD for All Options. FIGURE 3-8: Noise vs. Frequency, No Load, TA = +25°C. FIGURE 3-9: PSRR vs. Frequency, No Load, TA = +25°C. FIGURE 3-10: PSRR vs. Frequency, 1 kΩ Load, TA = +25°C. FIGURE 3-11: Dropout Voltage vs. Load, TA = +25°C. FIGURE 3-12: MCP1502 Tempco Distribution, No Load, VDD = 2.7V. FIGURE 3-13: MCP1502 Tempco Distribution, No Load, VDD = 5.5V. FIGURE 3-14: VOUT Drift vs. Time, TA = +25°C, No Load, 800 Units. FIGURE 3-15: MCP1502-10 VREF and Load Regulation vs. Load Current. FIGURE 3-16: MCP1502-20 VREF and Load Regulation vs. Load Current. FIGURE 3-17: MCP1502-40 VREF and Load Regulation vs. Load Current. FIGURE 3-18: MCP1502 Output Voltage Histogram, VDD = 2.7V. FIGURE 3-19: MCP1502 Output Voltage Histogram, VDD = 5.5V. FIGURE 3-20: Fast Ramp Start-up @ +25°C for All Options. FIGURE 3-21: Slow Ramp Start-up @ +25°C for All Options. FIGURE 3-22: IDD Turn-On Transient Response. FIGURE 3-23: Shutdown Low-to-High Slow Ramp Turn-On Transient Response @ +25°C for All Options. FIGURE 3-24: Load Regulation Transient Response @ +25°C for All Options. FIGURE 3-25: Line Regulation Transient Response @ +25°C for All Options. FIGURE 3-26: MCP1502-10 Transient Response vs. Capacitive Load, VDD = 5V. FIGURE 3-27: MCP1502-20 Transient Response vs. Capacitive Load, VDD = 5V. FIGURE 3-28: MCP1502-40 Transient Response vs. Capacitive Load, VDD = 5V. FIGURE 3-29: MCP1502-10 Transient Response vs. RS, VDD = 5V, CL = 4.7 nF. FIGURE 3-30: MCP1502-20 Transient Response vs. RS, VDD = 5V, CL = 4.7 nF. FIGURE 3-31: MCP1502-40 Transient Response vs. RS, VDD = 5V, CL = 4.7 nF. FIGURE 3-32: MCP1502-10 Transient Response vs. VDD, CL = 4.7 nF. FIGURE 3-33: MCP1502-20 Transient Response vs. VDD, CL = 4.7 nF. FIGURE 3-34: MCP1502-40 Transient Response vs. VDD, CL = 4.7 nF. 4.0 Theory of Operation 5.0 Application Circuits 5.1 Application Tips 5.1.1 Basic Application Circuit FIGURE 5-1: Basic Circuit Configuration. FIGURE 5-2: Output Noise Reducing Filter. EQUATION 5-1: 5.1.2 Load Capacitor 5.1.3 Printed Circuit Board Layout Considerations 5.2 Typical Applications Circuits 5.2.1 Negative Voltage Reference FIGURE 5-3: Negative Voltage Reference. 5.2.2 A/D Converter Reference FIGURE 5-4: ADC Example Circuit. FIGURE 5-5: SAR ADC Example Circuit. 6.0 Package Information 6.1 Package Markings Appendix A: Revision History Revision A (September 2021) Product Identification System Worldwide Sales and Service