AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK General Description Features The AAT3223 PowerLinear NanoPower low dropout (LDO) linear regulator is ideal for portable applications where extended battery life is critical. This device features extremely low quiescent current which is typically 1.1µA. Dropout voltage is also very low, typically 190mV at 100mA. The AAT3223 has an enable pin feature which, when pulled low, will put the LDO regulator into shutdown mode, removing power from its load and offering extended power conservation capabilities for portable battery-powered applications. The AAT3223 also has a Power-OK (POK) feature. The POK function monitors the LDO output voltage and will alert the system if the output falls out of regulation. • • • • • • • • • • • • • • The AAT3223 has output short-circuit and overcurrent protection. In addition, the device has an over-temperature protection circuit, which will shut down the LDO regulator during extended over-current events. PowerLinear™ 1.1µA Quiescent Current 250mA Output Current Low Dropout: 190mV (typical) High Accuracy: ±2% Current Limit Protection Over-Temperature Protection Extremely Low Power Shutdown Mode Low Temperature Coefficient Stable Operation With Virtually Any Output Capacitor Type Power-OK Signal Output Active High Enable Pin 4kV ESD Factory-Programmed Output Voltages 6-pin SOT23 Package Applications • • • • • • • The AAT3223 is available in a space-saving 6-pin SOT23 package and is rated over the -40°C to +85°C temperature range. The AAT3223 is similar to the AAT3221 with the exception that it offers the additional Power-OK function through the POK pin. Cellular Phones Digital Cameras Handheld Electronics Notebook Computers PDAs Portable Communication Devices Remote Controls Typical Application VIN IN AAT3223 1µF ON/OFF GND 3223.2005.04.1.4 OUT EN 100k POK GND VOUT 1µF POK GND 1 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Pin Descriptions Pin # Symbol Function 1 IN 2 GND Ground connection pin. 3 OUT Output pin. This pin should be decoupled with a 1µF or larger capacitor. 4 N/C Not connected. 5 EN Enable input. Active high, logic level compatible. 6 POK Input pin. It is recommended to bypass this pin with a 1µF capacitor. Power-OK output pin. This pin is pulled to ground during a power failure; it is normally high impedance and should have a 100kΩ pull-up resistor connected to OUT. Pin Configuration SOT23-6 (Top View) 2 IN 1 6 POK GND 2 5 EN OUT 3 4 N/C 3223.2005.04.1.4 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Absolute Maximum Ratings1 TA=25°C, unless otherwise noted. Symbol VIN VEN VENIN(MAX) IOUT TJ TLEAD Description Input Voltage EN to GND Voltage Maximum EN to Input Voltage Maximum DC Output Current Operating Junction Temperature Range Maximum Soldering Temperature (at leads, 10 sec) Value Units -0.3 to 6 -0.3 to 6 0.3 PD/(VIN-VO) -40 to 150 300 V V V mA °C °C Rating Units 150 667 °C/W mW Rating Units (VOUT+VDO) to 5.5 -40 to +85 V °C Thermal Information2 Symbol ΘJA PD Description Thermal Resistance (SOT23-6) Power Dissipation (SOT23-6) (TA = 25°C)3 Recommended Operating Conditions Symbol VIN T Description 4 Input Voltage Ambient Temperature Range 1. Stresses above those listed in Absolute Maximum Ratings may cause permanent damage to the device. Functional operation at conditions other than the operating conditions specified is not implied. Only one Absolute Maximum Rating should be applied at any one time. 2. Mounted on a demo board. 3. Derate 6.7mW/°C above 25°C. 4. To calculate minimum input voltage, use the following equation: VIN(MIN) = VOUT(MAX) + VDO(MAX) as long as VIN ≥ 2.5V. 3223.2005.04.1.4 3 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Electrical Characteristics VIN = VOUT(NOM) + 1V, IOUT = 1mA, COUT = 1µF, TA = 25°C, unless otherwise noted. Symbol VOUT IOUT ISC IQ IQ-OFF ∆VOUT/VOUT ∆VOUT/VOUT VDO PSRR TSD THYS eN TC Description DC Output Voltage Tolerance Output Current Short-Circuit Current Ground Current Off-Supply Current Line Regulation Load Regulation Dropout Voltage1, 2 Power Supply Rejection Ratio Over-Temperature Shutdown Threshold Over-Temperature Shutdown Hysteresis Output Noise Output Voltage Temperature Coefficient Conditions VOUT > 1.2V VOUT < 0.4V VIN = 5V, No Load VIN = 5V, EN = Inactive VIN = 4.0V to 5.5V VOUT = 1.8 VOUT = 2.7 VOUT = 2.8 IL=1 to 100mA VOUT = 2.85 VOUT = 3.0 VOUT = 3.3 VOUT = 2.7 VOUT = 2.8 IOUT = 100mA VOUT = 2.85 VOUT = 3.0 VOUT = 3.3 100Hz Min Typ -2.0 250 400 1.1 0.01 0.15 1.0 0.7 0.7 0.7 0.6 0.5 200 190 190 190 180 50 Max Units 2.0 % mA mA µA µA %/V 2.5 1 0.4 1.65 1.25 1.20 1.20 1.15 1.00 240 235 230 225 220 % mV dB 140 °C 20 °C 350 µVRMS 80 PPM/°C POK POKTH POK Trip Threshold POKHYS IPOK VPOK TPOK EN VIH VIL IEN(SINK) POK POK POK POK Falling Hysteresis Off-Current Low Voltage Delay EN Input Threshold EN Input Threshold EN Input Leakage 25°C -40 to 85°C 87.5 86 90.5 93.5 95 1.5 VPOK = 5.5V, TA = 25°C IPOK = 1mA VOUT Rising VIN = 2.5V to 5.5V VIN = 2.5V to 5.5V VON = 5.5V 100 200 1.5 2 0.01 0.5 1 % of VOUT nA mV ms V µA 1. VDO is defined as VIN - VOUT when VOUT is 98% of nominal. 2. For VOUT < 2.3V, VDO = 2.5V - VOUT. 4 3223.2005.04.1.4 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Typical Characteristics Unless otherwise noted, VIN = VOUT + 1V, TA = 25°C, CIN = COUT = 1µF ceramic. Output Voltage vs. Input Voltage 3.03 3.1 3.02 3 Output Voltage (V) Output Voltage (V) Output Voltage vs. Output Current 3.01 -30°C 3 25°C 2.99 80°C 2.98 1mA 2.9 40mA 2.8 2.7 10mA 2.6 2.5 2.97 0 20 40 60 80 2.7 100 2.9 Output Current (mA) Dropout Voltage (mV) Output Voltage (V) 3.5 Dropout Voltage vs. Output Current 3.03 1mA 10mA 3.01 40mA 3 40 0 300 80°C 200 25°C -30°C 100 0 2.99 3.5 4 4.5 5 0 5.5 25 50 75 100 125 150 Output Current (mA) Input Voltage (V) Supply Current vs. Input Voltage PSRR With 10mA Load 60 2.0 1.8 80°C 1.6 1.4 PSRR (dB) Input (µA) with No Load 3.3 Input Voltage (V) Output Voltage vs. Input Voltage 3.02 3.1 25°C 1.2 1.0 0.8 0.6 -30°C 40 20 0.4 0.2 0.0 0 1 2 3 4 Input Voltage (V) 3223.2005.04.1.4 5 6 0 1.E+01 1.E+02 1.E+03 1.E+04 1.E+05 Frequency (Hz) 5 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Typical Characteristics Unless otherwise noted, VIN = VOUT + 1V, TA = 25°C, CIN = COUT = 1µF ceramic. Line Response With 1mA Load 3.8 20 3.6 Output Voltage (V) 30 10 0 -10 -20 1.E+02 1.E+03 1.E+04 1.E+05 4 3.2 3 3 2 Output 2.8 1 0 6 3.8 5 3.6 3.4 4 3.2 3 3 2 Output 2.8 1 0 200 400 600 5 Input 3.4 4 3.2 3 3 2 Output 2.8 2.6 -200 0 800 6 1 0 0 800 600 80 2 0 2 3 Output Voltage (V) 160 320 240 Output 3 160 80 2 Output Current (mA) Output 3 4 Output Current (mA) 240 Time (ms) 400 Load Transient - 1mA / 80mA 320 1 200 Time (µs) 4 0 Input Voltage (V) Input Load Transient - 1mA / 40mA Output Voltage (V) 0 800 600 Line Response With 100mA Load Time (µs) 6 400 Line Response With 10mA Load 3.6 -1 200 Time (µs) Input Voltage (V) Output Voltage (V) 3.4 Frequency (Hz) 3.8 2.6 -200 5 Input 2.6 -200 1.E+06 Output Voltage (V) -30 1.E+01 6 Input Voltage (V) Noise (dB µV/rt Hz ) Noise Spectrum 0 -1 0 1 2 3 Time (ms) 3223.2005.04.1.4 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Typical Characteristics Unless otherwise noted, VIN = VOUT + 1V, TA = 25°C, CIN = COUT = 1µF ceramic. Turn-On With 1mA Load Power-Up With 1mA Load OUT (1V/div) IN (1V/div) POK (1V/div) OUT (1V/div) POK (1V/div) -1 0 1 2 3 4 EN (1V/div) -1 5 0 1 2 3 Power-Up With 10mA Load Turn-On With 10mA Load IN (1V/div) OUT (1V/div) POK (1V/div) OUT (1V/div) POK (1V/div) 0 1 2 3 EN (1V/div) 4 5 -1 0 1 2 3 4 Time (ms) Tim e (m s) Power-Up With 100mA Load Turn-On With 100mA Load IN (1V/div) POK (1V/div) POK (1V/div) 0 1 2 Time (ms) 3223.2005.04.1.4 3 4 5 OUT (1V/div) OUT (1V/div) -1 5 Time (ms) Time (ms) -1 4 EN (1V/div) 5 -1 0 1 2 3 4 5 Time (ms) 7 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Typical Characteristics Unless otherwise noted, VIN = VOUT + 1V, TA = 25°C, CIN = COUT = 1µF ceramic. Current Limit Response Power-Off from 100mA Load OUT (1V/div) -1 0 1 2 OUT (1V/div) POK (1V/div) POK (1V/div) EN (1V/div) IOUT (200mA/div) 3 4 5 -200 0 200 400 600 800 1000 Time (ms) Time (µs) EN Threshold vs. Input Voltage EN Threshold (V) 1.50 1.25 -30°C 1.00 0.75 25°C 80°C 0.50 3.0 3.5 4.0 4.5 5.0 5.5 Input Voltage (V) 8 3223.2005.04.1.4 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Functional Block Diagram IN OUT Over-Current Protection Over-Temperature Protection POK + Error Amplifier EN - - + 1ms Delay 91% VREF Voltage Reference GND Functional Description The AAT3223 is intended for LDO regulator applications where output current load requirements range from no load to 250mA. The advanced circuit design of the AAT3223 has been optimized for very low quiescent or ground current consumption, making it ideal for use in power management systems in small battery-operated devices. The typical quiescent current level is just 1.1µA. The AAT3223 also contains an enable circuit, which has been provided to shut down the LDO regulator for additional power conservation in portable products. In the shutdown state, the LDO draws less than 1µA from input supply. The Power-OK function has been incorporated to allow notification to application circuits when the output voltage falls out of regulation. If the output voltage falls below the regulation threshold limit, which is compared to a level set by the internal voltage reference, the POK pin is pulled to ground through an N-channel MOSFET. 3223.2005.04.1.4 The LDO also demonstrates excellent power supply ripple rejection, and load and line transient response characteristics. The AAT3223 is a truly high performance LDO regulator that is especially well suited for circuit applications which are sensitive to load circuit power consumption and extended battery life. The LDO regulator output has been specifically optimized to function with low-cost, low equivalent series resistance (ESR) ceramic capacitors; however, the design will allow for operation over a wide range of capacitor types. The AAT3223 has complete short-circuit and thermal protection. The integral combination of these two internal protection circuits give the AAT3223 a comprehensive safety system to guard against extreme adverse operating conditions. Device power dissipation is limited to the package type and thermal dissipation properties. Refer to the Thermal Considerations section of this datasheet for details on device operation at maximum output current loads. 9 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Applications Information To assure the maximum possible performance is obtained from the AAT3223, please refer to the following application recommendations. needed can be calculated from the step size of the change in output load current expected and the voltage excursion that the load can tolerate. The total output capacitance required can be calculated using the following formula: Input Capacitor Typically, a 1µF or larger capacitor is recommended for CIN in most applications. A CIN capacitor is not required for basic LDO regulator operation. However, if the AAT3223 is physically located any distance more than one or two centimeters from the input power source, a CIN capacitor will be needed for stable operation. CIN should be located as closely to the device VIN pin as practically possible. CIN values greater than 1µF will offer superior input line transient response and will assist in maximizing the power supply ripple rejection. Ceramic, tantalum, or aluminum electrolytic capacitors may be selected for CIN, as there is no specific capacitor ESR requirement. For 250mA LDO regulator output operation, ceramic capacitors are recommended for CIN due to their inherent capability over tantalum capacitors to withstand input current surges from low impedance sources such as batteries in portable devices. COUT = ∆I × 15µF ∆V Where: ∆I = maximum step in output current ∆V = maximum excursion in voltage that the load can tolerate Note that use of this equation results in capacitor values approximately two to four times the typical value needed for an AAT3223 at room temperature. The increased capacitor value is recommended if tight output tolerances must be maintained over extreme operating conditions and maximum operational temperature excursions. If tantalum or aluminum electrolytic capacitors are used, the capacitor value should be increased to compensate for the substantial ESR inherent to these capacitor types. Capacitor Characteristics Output Capacitor For proper load voltage regulation and operational stability, a capacitor is required between pins VOUT and GND. The COUT capacitor connection to the LDO regulator ground pin should be made as direct as practically possible for maximum device performance. The AAT3223 has been specifically designed to function with very low ESR ceramic capacitors. Although the device is intended to operate with these low ESR capacitors, it is stable over a very wide range of capacitor ESR, thus it will also work with some higher ESR tantalum or aluminum electrolytic capacitors. However, for best performance, ceramic capacitors are recommended. The value of COUT typically ranges from 0.47µF to 10µF; however, 1µF is sufficient for most operating conditions. If large output current steps are required by an application, then an increased value for COUT should be considered. The amount of capacitance 10 Ceramic composition capacitors are highly recommended over all other types of capacitors for use with the AAT3223. Ceramic capacitors offer many advantages over their tantalum and aluminum electrolytic counterparts. A ceramic capacitor typically has very low ESR, is lower cost, has a smaller PCB footprint, and is non-polarized. Line and load transient response of the LDO regulator is improved by using low-ESR ceramic capacitors. Since ceramic capacitors are non-polarized, they are less prone to damage if incorrectly connected. Equivalent Series Resistance: ESR is a very important characteristic to consider when selecting a capacitor. ESR is the internal series resistance associated with a capacitor that includes lead resistance, internal connections, capacitor size and area, material composition, and ambient temperature. Typically, capacitor ESR is measured in milliohms for ceramic capacitors and can range to more than several ohms for tantalum or aluminum electrolytic capacitors. 3223.2005.04.1.4 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Ceramic Capacitor Materials: Ceramic capacitors less than 0.1µF are typically made from NPO or C0G materials. NPO and C0G materials are typically tight tolerance and are very stable over temperature. Larger capacitor values are typically composed of X7R, X5R, Z5U, and Y5V dielectric materials. Large ceramic capacitors, typically greater than 2.2µF, are often available in the lowcost Y5V and Z5U dielectrics. These two material types are not recommended for use with LDO regulators since the capacitor tolerance can vary more than ±50% over the operating temperature range of the device. A 2.2µF Y5V capacitor could be reduced to 1µF over the full operating temperature range. This can cause problems for circuit operation and stability. X7R and X5R dielectrics are much more desirable. The temperature tolerance of X7R dielectric is better than ±15%. Capacitor area is another contributor to ESR. Capacitors that are physically large in size will have a lower ESR when compared to a smaller sized capacitor of equivalent material and capacitance value. These larger devices can also improve circuit transient response when compared to an equal value capacitor in a smaller package size. Consult capacitor vendor data sheets carefully when selecting capacitors for use with LDO regulators. resistor (100kΩ is a good resistor value for this purpose). An internal comparator has a reference threshold set to trigger at 10% of the nominal AAT3223 output voltage. If the output voltage level drops below this preset threshold, the POK function will become active and turn on an open-drain N-channel MOSFET to pull the POK output pin to ground. There is a fixed 1ms delay circuit between the POK comparator output and the N-channel MOSFET gate. The purpose of the delay is to prevent a false triggering of the POK output during device turn-on or during very short duration load transient events. If necessary, additional POK flag delay can be added by placing a capacitor in parallel with the POK pull-up resistor. The additional delay time will be set by the RC time constant, the pull-up resistor, and parallel capacitor values. When the AAT3223 is in the shutdown state with the EN pin low, the POK pin becomes low impedance. The LDO output will be discharged through the high value POK pull-up resistor. When entering the shutdown state, there is no delay associated with the POK output; the open-drain device turns on immediately. This offers the added advantage of having a hard application turn-off when the LDO regulator is turned off. This additional function has no adverse effect on regulator turn-on time. Enable Function The AAT3223 features an LDO regulator enable / disable function. This pin (EN) is compatible with CMOS logic. For a logic high signal, the EN control level must be greater than 2.0 volts. A logic low signal is asserted when the voltage on the EN pin falls below 0.5 volts. For example, the active high version AAT3223 will turn on when a logic high is applied to the EN pin. If the enable function is not needed in a specific application, it may be tied to the respective voltage level to keep the LDO regulator in a continuously on state; e.g., the active high version AAT3223 will tie VIN to EN to remain on. Power-OK Function The Power-OK (POK) function is a very useful basic active low error flag. When the AAT3223 output voltage level is within regulation limits, the POK output pin is a high impedance and should be tied high to the LDO output through a high value 3223.2005.04.1.4 Short-Circuit and Thermal Protection The AAT3223 is protected by both current limit and over-temperature protection circuitry. The internal short-circuit current limit is designed to activate when the output load demand exceeds the maximum rated output. If a short-circuit condition were to continually draw more than the current limit threshold, the LDO regulator's output voltage will drop to a level necessary to supply the current demanded by the load. Under short-circuit or other over-current operating conditions, the output voltage will drop and the AAT3223's die temperature will rapidly increase. Once the regulator's power dissipation capacity has been exceeded and the internal die temperature reaches approximately 140°C, the system thermal protection circuit will become active. The internal thermal protection circuit will actively turn off the LDO regulator output pass device to prevent the possibility of over-temperature damage. The LDO regulator output will 11 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK remain in a shutdown state until the internal die temperature falls back below the 140°C trip point. The interaction between the short-circuit and thermal protection systems allows the LDO regulator to withstand indefinite short-circuit conditions without sustaining permanent damage. No-Load Stability The AAT3223 is designed to maintain output voltage regulation and stability under operational noload conditions. This is an important characteristic for applications where the output current may drop to zero. An output capacitor is required for stability under no-load operating conditions. Refer to the Output Capacitor section of this datasheet for recommended typical output capacitor values. Thermal Considerations and High Output Current Applications The AAT3223 is designed to deliver a continuous output load current up to 250mA under normal operating conditions. The limiting characteristic for the maximum output load safe operating area is essentially package power dissipation and the internal preset thermal limit of the device. In order to obtain high operating currents, careful device layout and circuit operating conditions must be taken into account. The following discussions will assume the LDO regulator is mounted on a printed circuit board utilizing the minimum recommended footprint and the printed circuit board is 0.062-inch thick FR4 material with one ounce copper. At any given ambient temperature (TA), the maximum package power dissipation can be determined by the following equation: Constants for the AAT3223 are TJ(MAX), the maximum junction temperature for the device which is 125°C, and ΘJA = 150°C/W, the package thermal resistance. Typically, maximum conditions are calculated at the maximum operating temperature where TA = 85°C, under normal ambient conditions TA = 25°C. Given TA = 85°C, the maximum package power dissipation is 267mW. At TA = 25°C, the maximum package power dissipation is 667mW. The maximum continuous output current for the AAT3223 is a function of the package power dissipation and the input-to-output voltage drop across the LDO regulator. Refer to the following simple equation: IOUT(MAX) < PD(MAX) VIN - VOUT For example, if VIN = 5V, VOUT = 2.8V and TA = 25°C, IOUT(MAX) < 267mA. The output short-circuit protection threshold is set between 300mA and 450mA. If the output load current were to exceed 267mA or if the ambient temperature were to increase, the internal die temperature will increase. If the condition remained constant and the shortcircuit protection did not activate, there would be a potential damage hazard to the LDO regulator since the thermal protection circuit will only activate after a short-circuit event occurs on the LDO regulator output. To determine the maximum input voltage for a given load current, refer to the following equation. This calculation accounts for the total power dissipation of the LDO regulator, including that caused by ground current. PD(MAX) = (VIN - VOUT)IOUT + (VIN x IGND) PD(MAX) = TJ(MAX) - TA θJA This formula can be solved for VIN to determine the maximum input voltage. VIN(MAX) = 12 PD(MAX) + (VOUT × IOUT) IOUT + IGND 3223.2005.04.1.4 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK The following is an example for an AAT3223 set for a 2.8V output: VOUT = 2.9V IOUT = 250mA IGND = 1.1µA VIN(MAX) = 667mW + (2.8V × 150mA) 150mA + 1.1µA VIN(MAX) = 9.11V From the discussion above, PD(MAX) was determined to equal 667mW at TA = 25°C. Thus, the AAT3223 can sustain a constant 2.8V output at a 150mA load current as long as VIN is ≤9.11V at an ambient temperature of 25°C. 5.5V is the maximum input operating voltage for the AAT3223, thus at 25°C, the device would not have any thermal concerns or operational VIN(MAX) limits. This situation can be different at 85°C. The following is an example for an AAT3223 set for a 2.8V output at 85°C: VOUT = 2.9V IOUT = 150mA IGND = 1.1µA VIN(MAX) = 267mW + (2.8V × 150mA) 150mA + 1.1µA VIN(MAX) = 4.58V From the discussion above, PD(MAX) was determined to equal 267mW at TA = 85°C. 3223.2005.04.1.4 Higher input-to-output voltage differentials can be obtained with the AAT3223, while maintaining device functions in the thermal safe operating area. To accomplish this, the device thermal resistance must be reduced by increasing the heat sink area or by operating the LDO regulator in a duty-cycled mode. For example, an application requires VIN = 5.0V while VOUT = 2.8V at a 150mA load and TA = 85°C. VIN is greater than 4.58V, which is the maximum safe continuous input level for VOUT = 2.8V at 150mA for TA = 85°C. To maintain this high input voltage and output current level, the LDO regulator must be operated in a duty-cycled mode. Refer to the following calculation for duty-cycle operation: IGND = 1.1µA IOUT = 150mA VIN = 5.0V VOUT = 2.8V %DC = 100 PD(MAX) (VIN - VOUT)IOUT + (VIN × IGND) %DC = 100 267mW (5.0V - 2.8V)150mA + (5.0V × 1.1µA) %DC = 80.9% PD(MAX) was assumed to be 267mW. For a 150mA output current and a 2.2V drop across the AAT3223 at an ambient temperature of 85°C, the maximum on-time duty cycle for the device would be 80.9%. The following family of curves shows the safe operating area for duty-cycled operation from ambient room temperature to the maximum operating level. 13 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK + High Peak Output Current Applications Device Duty Cycle vs. VDROP (VDROP = 2.8V @ 25°C) 4 250mA Voltage Drop (V) 3.5 3 2.5 300mA 2 1.5 Duty Cycle (%) For example, a 2.8V system using a AAT3223IGU2.8-T1 operates at a continuous 100mA load current level and has short 250mA current peaks. The current peak occurs for 378µs out of a 4.61ms period. It will be assumed the input voltage is 5.0V. Device Duty Cycle vs. VDROP First, the current duty cycle percentage must be calculated: 1 0.5 0 0 10 20 30 40 50 60 70 80 90 100 (VDROP = 2.8V @ 50°C) % Peak Duty Cycle: X/100 = 378ms/4.61ms % Peak Duty Cycle = 8.2% 4 200mA Voltage Drop (V) 3.5 3 2.5 2 300mA 1.5 250mA 1 0.5 0 0 10 20 30 40 50 60 70 80 90 100 Duty Cycle (%) (VDROP = 2.8V @ 85°C) 200mA Voltage Drop (V) 100mA 150mA 3 2.5 2 1.5 PD(MAX) PD(250mA) PD(250mA) 250mA 1 300mA 0.5 0 0 10 20 30 40 50 60 Duty Cycle (%) PD(MAX) PD(100mA) PD(100mA) 70 80 = (VIN - VOUT)IOUT + (VIN x IGND) = (5.0V - 2.8V)100mA + (5.0V x 1.1µA) = 225.5mW The power dissipation for a 100mA load occurring for 91.8% of the duty cycle will be 207mW. Now the power dissipation for the remaining 8.2% of the duty cycle at the 150mA load can be calculated: 4 3.5 The LDO regulator will be under the 100mA load for 91.8% of the 4.61ms period and have 150mA peaks occurring for 8.2% of the time. Next, the continuous nominal power dissipation for the 100mA load should be determined and then multiplied by the duty cycle to conclude the actual power dissipation over time. PD(91.8%D/C) = %DC x PD(100mA) PD(91.8%D/C) = 0.918 x 225.5mW PD(91.8%D/C) = 207mW Device Duty Cycle vs. VDROP 14 Some applications require the LDO regulator to operate at continuous nominal levels with short duration, high-current peaks. The duty cycles for both output current levels must be taken into account. To do so, one would first need to calculate the power dissipation at the nominal continuous level, then factor in the addition power dissipation due to the short duration, high-current peaks. 90 100 = (VIN - VOUT)IOUT + (VIN x IGND) = (5.0V - 2.8V)250mA + (5.0V x 1.1µA) = 550mW PD(8.2%D/C) = %DC x PD(250mA) PD(8.2%D/C) = 0.082 x 550mW PD(8.2%D/C) = 45.1mW 3223.2005.04.1.4 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK The power dissipation for a 150mA load occurring for 8.2% of the duty cycle will be 20.9mW. Finally, the two power dissipation levels can summed to determine the total true power dissipation under the varied load. PD(total) = PD(100mA) + PD(250mA) PD(total) = 207mW + 45.1mW PD(total) = 252.1mW The maximum power dissipation for the AAT3223 operating at an ambient temperature of 85°C is 267mW. The device in this example will have a total power dissipation of 252.1mW. This is within the thermal limits for safe operation of the device. 3223.2005.04.1.4 Printed Circuit Board Layout Recommendations In order to obtain the maximum performance from the AAT3223 LDO regulator, very careful attention must be considered in regard to the printed circuit board layout. If grounding connections are not properly made, power supply ripple rejection and LDO regulator transient response can be compromised. The LDO regulator external capacitors CIN and COUT should be connected as directly as possible to the ground pin of the LDO regulator. For maximum performance with the AAT3223, the ground pin connection should then be made directly back to the ground or common of the source power supply. If a direct ground return path is not possible due to printed circuit board layout limitations, the LDO ground pin should then be connected to the common ground plane in the application layout. 15 AAT3223 250mA NanoPower™ LDO Linear Regulator with Power-OK Ordering Information Output Voltage Enable 1.8V 2.7V 2.8V 2.85V 3.0V 3.3V Active Active Active Active Active Active Package Marking1 Part Number (Tape and Reel)2 SOT23-6 SOT23-6 SOT23-6 SOT23-6 SOT23-6 SOT23-6 EGXYY GGXYY EHXYY GFXYY GEXYY GQXYY AAT3223IGU-1.8-T1 AAT3223IGU-2.7-T1 AAT3223IGU-2.8-T1 AAT3223IGU-2.85-T1 AAT3223IGU-3.0-T1 AAT3223IGU-3.3-T1 high high high high high high Package Information SOT23-6 2.85 ± 0.15 1.90 BSC 2.80 ± 0.20 1.20 ± 0.25 0.15 ± 0.07 4° ± 4° 1.10 ± 0.20 0.075 ± 0.075 1.575 ± 0.125 0.95 BSC 10° ± 5° 0.40 ± 0.10 × 6 0.60 REF 0.45 ± 0.15 GAUGE PLANE 0.10 BSC All dimensions in millimeters. 1. XYY = assembly and date code. 2. Sample stock is generally held on all part numbers listed in BOLD. 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Testing and other quality control techniques are utilized to the extent AnalogicTech deems necessary to support this warranty. Specific testing of all parameters of each device is not necessarily performed. Advanced Analogic Technologies, Inc. 830 E. Arques Avenue, Sunnyvale, CA 94085 Phone (408) 737-4600 Fax (408) 737-4611 16 3223.2005.04.1.4 Form#: FOR001 Rev. D