Datasheet TC55 (Microchip) - 10
| Manufacturer | Microchip |
| Description | 1 µA Low Dropout Positive Voltage Regulator - Obsolete Device |
| Pages / Page | 18 / 10 — TC55. 5.0. THERMAL CONSIDERATIONS. EQUATION. 5.1. Power Dissipation. … |
| File Format / Size | PDF / 376 Kb |
| Document Language | English |
TC55. 5.0. THERMAL CONSIDERATIONS. EQUATION. 5.1. Power Dissipation. Junction Temperature. SOT-23 Example:. SOT-89 Example:
Model Line for this Datasheet
- 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
Text Version of Document
TC55 5.0 THERMAL CONSIDERATIONS EQUATION
P
5.1 Power Dissipation
D = (VINMAX – VOUTMIN) x IOUTMAX The amount of power dissipated internal to the low Given: dropout linear regulator is the sum of the power dissi- VIN = 3.3V to 4.1V pation within the linear pass device (P-Channel MOS- V FET) and the quiescent current required to bias the OUT = 3.0 V ± 2% internal reference and error amplifier. The internal lin- IOUT = 1 mA to 100 mA ear pass device power dissipation is calculated by mul- TAMAX = 55°C tiplying the voltage across the linear device by the P current through the device. MAX = (4.1V – (3.0V x 0.98)) x 100 mA PMAX = 116.0 milliwatts
EQUATION
To determine the junction temperature of the device, the thermal resistance from junction-to-ambient must be PD (Pass Device) = (VIN – VOUT) x IOUT known. The 3-pin SOT-23 thermal resistance from junc- The internal power dissipation, as a result of the bias tion-to-air (RθJA) is estimated to be approximately current for the LDO internal reference and error 359°C/W. The SOT-89 RθJA is estimated to be approxi- amplifier, is calculated by multiplying the ground or mately 110°C/W when mounted on 1 square inch of quiescent current by the input voltage. copper. The TO-92 RθJA is estimated to be 131.9°C/W. The RθJA will vary with physical layout, airflow and other application-specific conditions.
EQUATION
The device junction temperature is determined by PD (Bias) = VIN x IGND calculating the junction temperature rise above ambient, then adding the rise to the ambient The total internal power dissipation is the sum of PD temperature. (Pass Device) and PD (Bias).
EQUATION EQUATION Junction Temperature
PTOTAL = PD (Pass Device) + PD (Bias)
SOT-23 Example:
T For the TC55, the internal quiescent bias current is so J = PDMAX x RθJA + TA low (1 µA typical) that the P T D (Bias) term of the power J = 116.0 milliwatts x 359°C/W + 55°C dissipation equation can be ignored. The maximum TJ = 96.6°C power dissipation can be estimated by using the
SOT-89 Example:
maximum input voltage and the minimum output T voltage to obtain a maximum voltage differential J = 116.0 milliwatts x 110°C/W + 55°C between input and output. The next step would be to TJ = 67.8°C multiply the maximum voltage differential by the
TO-92 Example:
maximum output current. TJ = 116.0 milliwatts x 131.9°C/W + 55°C TJ = 70.3°C DS21435F-page 10 © 2005 Microchip Technology Inc. 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
P
5.1 Power Dissipation
D = (VINMAX – VOUTMIN) x IOUTMAX The amount of power dissipated internal to the low Given: dropout linear regulator is the sum of the power dissi- VIN = 3.3V to 4.1V pation within the linear pass device (P-Channel MOS- V FET) and the quiescent current required to bias the OUT = 3.0 V ± 2% internal reference and error amplifier. The internal lin- IOUT = 1 mA to 100 mA ear pass device power dissipation is calculated by mul- TAMAX = 55°C tiplying the voltage across the linear device by the P current through the device. MAX = (4.1V – (3.0V x 0.98)) x 100 mA PMAX = 116.0 milliwatts
EQUATION
To determine the junction temperature of the device, the thermal resistance from junction-to-ambient must be PD (Pass Device) = (VIN – VOUT) x IOUT known. The 3-pin SOT-23 thermal resistance from junc- The internal power dissipation, as a result of the bias tion-to-air (RθJA) is estimated to be approximately current for the LDO internal reference and error 359°C/W. The SOT-89 RθJA is estimated to be approxi- amplifier, is calculated by multiplying the ground or mately 110°C/W when mounted on 1 square inch of quiescent current by the input voltage. copper. The TO-92 RθJA is estimated to be 131.9°C/W. The RθJA will vary with physical layout, airflow and other application-specific conditions.
EQUATION
The device junction temperature is determined by PD (Bias) = VIN x IGND calculating the junction temperature rise above ambient, then adding the rise to the ambient The total internal power dissipation is the sum of PD temperature. (Pass Device) and PD (Bias).
EQUATION EQUATION Junction Temperature
PTOTAL = PD (Pass Device) + PD (Bias)
SOT-23 Example:
T For the TC55, the internal quiescent bias current is so J = PDMAX x RθJA + TA low (1 µA typical) that the P T D (Bias) term of the power J = 116.0 milliwatts x 359°C/W + 55°C dissipation equation can be ignored. The maximum TJ = 96.6°C power dissipation can be estimated by using the
SOT-89 Example:
maximum input voltage and the minimum output T voltage to obtain a maximum voltage differential J = 116.0 milliwatts x 110°C/W + 55°C between input and output. The next step would be to TJ = 67.8°C multiply the maximum voltage differential by the
TO-92 Example:
maximum output current. TJ = 116.0 milliwatts x 131.9°C/W + 55°C TJ = 70.3°C DS21435F-page 10 © 2005 Microchip Technology Inc. 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
