Datasheet TC55 (Microchip) - 9
| Hersteller | Microchip |
| Beschreibung | 1 µA Low Dropout Positive Voltage Regulator - Obsolete Device |
| Seiten / Seite | 18 / 9 — TC55. 3.0. PIN DESCRIPTIONS. 4.0. DETAILED DESCRIPTION. TABLE 3-1:. PIN … |
| Dateiformat / Größe | PDF / 376 Kb |
| Dokumentensprache | Englisch |
TC55. 3.0. PIN DESCRIPTIONS. 4.0. DETAILED DESCRIPTION. TABLE 3-1:. PIN FUNCTION TABLE. Pin No. Symbol. Description. 4.1. Output Capacitor. 3.1
Modelllinie für dieses Datenblatt
- TC55RP1201ECB713 TC55RP1201ECBTR TC55RP1201EMB713 TC55RP1201EMBTR TC55RP1201EZB713 TC55RP1201EZBTR TC55RP1202ECB713 TC55RP1202ECBTR TC55RP1202EMB713 TC55RP1202EMBTR TC55RP1202EZB713 TC55RP1202EZBTR TC55RP1801ECB713 TC55RP1801ECBTR TC55RP1801EMB713 TC55RP1801EMBTR TC55RP1801EZB713 TC55RP1801EZBTR TC55RP1802ECB713 TC55RP1802ECBTR TC55RP1802EMB713 TC55RP1802EMBTR TC55RP1802EZB713 TC55RP1802EZBTR TC55RP2501ECB713 TC55RP2501ECBTR TC55RP2501EMB713 TC55RP2501EMBTR TC55RP2501EZB713 TC55RP2501EZBTR TC55RP2502ECB713 TC55RP2502ECBTR TC55RP2502EMB713 TC55RP2502EMBTR TC55RP2502EZB713 TC55RP2502EZBTR TC55RP3001ECB713 TC55RP3001ECBTR TC55RP3001EMB713 TC55RP3001EMBTR TC55RP3001EZB713 TC55RP3001EZBTR TC55RP3002ECB713 TC55RP3002ECBTR TC55RP3002EMB713 TC55RP3002EMBTR TC55RP3002EZB713 TC55RP3002EZBTR TC55RP3301ECB713 TC55RP3301ECBTR TC55RP3301EMB713 TC55RP3301EMBTR TC55RP3301EZB713 TC55RP3301EZBTR TC55RP3302ECB713 TC55RP3302ECBTR TC55RP3302EMB713 TC55RP3302EMBTR TC55RP3302EZB713 TC55RP3302EZBTR TC55RP4001ECB713 TC55RP4001ECBTR TC55RP4001EMB713 TC55RP4001EMBTR TC55RP4001EZB713 TC55RP4001EZBTR TC55RP4002ECB713 TC55RP4002ECBTR TC55RP4002EMB713 TC55RP4002EMBTR TC55RP4002EZB713 TC55RP4002EZBTR TC55RP5001ECB713 TC55RP5001ECBTR TC55RP5001EMB713 TC55RP5001EMBTR TC55RP5001EZB713 TC55RP5001EZBTR TC55RP5002ECB713 TC55RP5002ECBTR TC55RP5002EMB713 TC55RP5002EMBTR TC55RP5002EZB713 TC55RP5002EZBTR
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TC55 3.0 PIN DESCRIPTIONS 4.0 DETAILED DESCRIPTION
The descriptions of the pins are listed in Table 3-1. The TC55 is a low quiescent current, precision, fixed- output voltage LDO. Unlike bipolar regulators, the
TABLE 3-1: PIN FUNCTION TABLE
TC55 supply current does not increase proportionally with load current.
Pin No. Symbol Description
1 GND Ground Terminal
4.1 Output Capacitor
2 VOUT Regulated Voltage Output A minimum of 1 µF output capacitor is required. The 3 V output capacitor should have an effective series resis- IN Unregulated Supply Input tance (esr) greater than 0.1Ω and less than 5Ω, plus a
3.1 Ground Terminal (GND)
resonant frequency above 1 MHz. Larger output capacitors can be used to improve supply noise rejec- Regulator ground. Tie GND to the negative side of the tion and transient response. Care should be taken output and the negative side of the input capacitor. when increasing COUT to ensure that the input imped- Only the LDO bias current (1 µA typical) flows out of ance is not high enough to cause high input impedance this pin, there is no high current. The LDO output regu- oscillation. lation is referenced to this pin. Minimize voltage drops between this pin and the minus side of the load.
4.2 Input Capacitor 3.2 Regulated Voltage Output (V
A 1 µF input capacitor is recommended for most
OUT)
applications when the input impedance is on the order Connect VOUT to the positive side of the load and the of 10Ω. Larger input capacitance may be required for positive terminal of the output capacitor. The positive stability when operating off of a battery input, or if there side of the output capacitor should be physically is a large distance from the input source to the LDO. located as close to the LDO VOUT pin as is practical. When large values of output capacitance are used, the The current flowing out of this pin is equal to the DC input capacitance should be increased to prevent high load current. source impedance oscillations.
3.3 Unregulated Supply Input (VIN)
Connect the input supply voltage and the positive side of the input capacitor to VIN. The input capacitor should be physically located as close as is practical to VIN. The current flow into this pin is equal to the DC load current, plus the LDO bias current (1 µA typical.) © 2005 Microchip Technology Inc. DS21435F-page 9 Document Outline 1.0 Electrical Characteristics 2.0 Typical Performance Curves FIGURE 2-1: Output Voltage vs. Output Current (TC55RP3002). FIGURE 2-2: Output Voltage vs. Input Voltage (TC55RP3002). FIGURE 2-3: Output Voltage vs. Input Voltage (TC55RP3002). FIGURE 2-4: Dropout Voltage vs. Output Current (TC55RP3002). FIGURE 2-5: Output Voltage vs. Operating Temperature (TC55RP3002). FIGURE 2-6: Supply Current vs. Input Voltage (TC55RP3002). FIGURE 2-7: Supply Current vs. Operating Temperature (TC55RP3002). FIGURE 2-8: Load Transient Response (TC55RP3002). FIGURE 2-9: Output Voltage vs. Output Current (TC55RP5002). FIGURE 2-10: Output Voltage vs. Input Voltage (TC55RP5002). FIGURE 2-11: Output Voltage vs. Input Voltage (TC55RP5002). FIGURE 2-12: Dropout Voltage vs. Output Current (TC55RP5002). FIGURE 2-13: Output Voltage vs. Operating Temperature (TC55RP5002). FIGURE 2-14: Supply Current vs. Input Voltage (TC55RP5002). FIGURE 2-15: Supply Current vs. Operating Temperature (TC55RP5002). FIGURE 2-16: Input Transient Response, 1mA (TC55RP5002). FIGURE 2-17: Input Transient Response, 10mA (TC55RP5002). FIGURE 2-18: Load Transient Response (TC55RP5002). 3.0 Pin Descriptions TABLE 3-1: Pin Function Table 3.1 Ground Terminal (GND) 3.2 Regulated Voltage Output (VOUT) 3.3 Unregulated Supply Input (VIN) 4.0 Detailed Description 4.1 Output Capacitor 4.2 Input Capacitor 5.0 Thermal Considerations 5.1 Power Dissipation 6.0 Packaging Information 6.1 Package Marking Information Worldwide Sales and Service Trademarks Worldwide Sales
TC55 3.0 PIN DESCRIPTIONS 4.0 DETAILED DESCRIPTION
The descriptions of the pins are listed in Table 3-1. The TC55 is a low quiescent current, precision, fixed- output voltage LDO. Unlike bipolar regulators, the
TABLE 3-1: PIN FUNCTION TABLE
TC55 supply current does not increase proportionally with load current.
Pin No. Symbol Description
1 GND Ground Terminal
4.1 Output Capacitor
2 VOUT Regulated Voltage Output A minimum of 1 µF output capacitor is required. The 3 V output capacitor should have an effective series resis- IN Unregulated Supply Input tance (esr) greater than 0.1Ω and less than 5Ω, plus a
3.1 Ground Terminal (GND)
resonant frequency above 1 MHz. Larger output capacitors can be used to improve supply noise rejec- Regulator ground. Tie GND to the negative side of the tion and transient response. Care should be taken output and the negative side of the input capacitor. when increasing COUT to ensure that the input imped- Only the LDO bias current (1 µA typical) flows out of ance is not high enough to cause high input impedance this pin, there is no high current. The LDO output regu- oscillation. lation is referenced to this pin. Minimize voltage drops between this pin and the minus side of the load.
4.2 Input Capacitor 3.2 Regulated Voltage Output (V
A 1 µF input capacitor is recommended for most
OUT)
applications when the input impedance is on the order Connect VOUT to the positive side of the load and the of 10Ω. Larger input capacitance may be required for positive terminal of the output capacitor. The positive stability when operating off of a battery input, or if there side of the output capacitor should be physically is a large distance from the input source to the LDO. located as close to the LDO VOUT pin as is practical. When large values of output capacitance are used, the The current flowing out of this pin is equal to the DC input capacitance should be increased to prevent high load current. source impedance oscillations.
3.3 Unregulated Supply Input (VIN)
Connect the input supply voltage and the positive side of the input capacitor to VIN. The input capacitor should be physically located as close as is practical to VIN. The current flow into this pin is equal to the DC load current, plus the LDO bias current (1 µA typical.) © 2005 Microchip Technology Inc. DS21435F-page 9 Document Outline 1.0 Electrical Characteristics 2.0 Typical Performance Curves FIGURE 2-1: Output Voltage vs. Output Current (TC55RP3002). FIGURE 2-2: Output Voltage vs. Input Voltage (TC55RP3002). FIGURE 2-3: Output Voltage vs. Input Voltage (TC55RP3002). FIGURE 2-4: Dropout Voltage vs. Output Current (TC55RP3002). FIGURE 2-5: Output Voltage vs. Operating Temperature (TC55RP3002). FIGURE 2-6: Supply Current vs. Input Voltage (TC55RP3002). FIGURE 2-7: Supply Current vs. Operating Temperature (TC55RP3002). FIGURE 2-8: Load Transient Response (TC55RP3002). FIGURE 2-9: Output Voltage vs. Output Current (TC55RP5002). FIGURE 2-10: Output Voltage vs. Input Voltage (TC55RP5002). FIGURE 2-11: Output Voltage vs. Input Voltage (TC55RP5002). FIGURE 2-12: Dropout Voltage vs. Output Current (TC55RP5002). FIGURE 2-13: Output Voltage vs. Operating Temperature (TC55RP5002). FIGURE 2-14: Supply Current vs. Input Voltage (TC55RP5002). FIGURE 2-15: Supply Current vs. Operating Temperature (TC55RP5002). FIGURE 2-16: Input Transient Response, 1mA (TC55RP5002). FIGURE 2-17: Input Transient Response, 10mA (TC55RP5002). FIGURE 2-18: Load Transient Response (TC55RP5002). 3.0 Pin Descriptions TABLE 3-1: Pin Function Table 3.1 Ground Terminal (GND) 3.2 Regulated Voltage Output (VOUT) 3.3 Unregulated Supply Input (VIN) 4.0 Detailed Description 4.1 Output Capacitor 4.2 Input Capacitor 5.0 Thermal Considerations 5.1 Power Dissipation 6.0 Packaging Information 6.1 Package Marking Information Worldwide Sales and Service Trademarks Worldwide Sales