APS13568 LED Driver with Integrated Micropower Hall-Effect Switch FEATURES AND BENEFITS DESCRIPTION • Micropower (25 μA, typical) when LED is off • Linear LED drive up to 150 mA • Omnipolar Hall-effect switch □□ Low drift over temperature □□ Solid-state reliability □□ Insensitive to physical stress • External LED-enable pin for direct on/off control • Hall-effect switch output □□ Supports secondary switches and/or LED drivers □□ Provides switch state for other functions □□ Selectable output polarity • Automotive-grade ruggedness and fault-tolerance □□ “K” temperature range qualified per AEC-Q100 □□ Reverse-battery and load-dump protection □□ Short-circuit protection □□ Thermal protection • Internal protection circuits enable 40 V load dump compliance without external protection components The APS13568 is an integrated circuit that combines an ultrasensitive, omnipolar, micropower Hall-effect switch with a linear programmable current regulator providing up to 150 mA to drive high brightness LEDs. The omnipolar Halleffect switch provides contactless control of the regulated LED current, which is set by a single reference resistor. This highly integrated solution offers high reliability and ease of design compared to a discrete solution. The Hall-effect switch operates with either a north or a south magnetic pole. The switch output polarity can be set with an external pulldown on the POL input pin. This allows the user to select whether the APS13568 switch output goes low when a magnet is present or when the magnetic field is removed. Chopper stabilization provides low switchpoint drift over temperature. The LED is turned on when the EN input goes low. This activelow input can be connected directly to the Hall switch output, SO, to turn the LED on when the switch output goes low. This flexible solution allows the user to connect additional slave switches, LED drivers, PWM, or microprocessor inputs to control when the LED is on. Optionally, an external capacitor can be used to adjust the fade-in/fade-out feature. APPLICATIONS • • • • Automotive glove boxes and storage Automotive vanity mirrors Task lighting Consumer electronics PACKAGE: 8-Pin SOICN with Exposed Thermal Pad (Suffix LJ) On-board protection for shorts to ground and thermal overload prevents damage to the APS13568 and LED string by limiting the regulated current until the short is removed and/or the chip temperature has reduced below the thermal threshold. Continued on the next page… Not to scale CBYPASS +V 0.1 µF RPU 4.7 kΩ VIN 150 mA SO EN RIREF 600 Ω LA HALL POL FADE IREF GND CFADE (optional) Figure 1: Typical Application Diagram APS13568-DS March 13, 2017 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 DESCRIPTION (continued) The device is packaged in an 8-pin SOICN (LJ) with an exposed pad for enhanced thermal dissipation. It is RoHS-compliant, with 100% matte-tin leadframe plating. The APS13568 is available in an “E” temperature version (up to 85°C) for industrial and consumer applications, as well as a “K” temperature version (up to 125°C) that is qualified per AEC-Q100 for automotive applications. SELECTION GUIDE Part Number Packing Package Temperature Range, TA (°C) APS13568KLJATR-T 3000 pieces per 13-in. reel 8-pin SOICN surface mount –40 to 125 APS13568ELJATR-T 3000 pieces per 13-in. reel 8-pin SOICN surface mount –40 to 85 RoHS COMPLIANT SPECIFICATIONS ABSOLUTE MAXIMUM RATINGS Characteristic Supply Voltage [1] Symbol VIN (VDD) Notes Rating Unit –18 to 30 V Pin EN VEN –18 to 30 V Pin LA VLA –0.3 to 30 V Pin SO VSO –0.3 to 30 V Pin IREF VIREF –0.3 to 6.5 V Pin FADE VFADE –0.3 to 6.5 V Pin POL Maximum Junction Temperature Storage Temperature VPOL –0.3 to 6.5 V TJ(MAX) 165 °C Tstg –65 to 170 °C This rating does not apply to extremely short voltage transients such as Load Dump and/or ESD. Those events have individual ratings, specific to the respective transient voltage event. 1 Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 2 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 Current Reference Sample & Hold Dynamic Offset Cancellation FUNCTIONAL BLOCK DIAGRAM Temp Monitor Clock/Logic LA Current Regulator Slew Limit Control Logic VREG Micropower Control Circuitry and Regulator VIN GND POL SO * FADE EN CBYP CFADE RPU IREF RIREF * SO can be pulled up to VIN or an external voltage source. PINOUT DRAWING AND TERMINAL LIST Terminal List VIN 8 1 EN 2 SO 3 LA 4 PAD GND 7 POL 6 IREF 5 FADE Package LJ, 8-Pin SOICN Pinout Drawing Pin Number Pin Name 1 VIN Supply voltage Description 2 EN Active-low LED drive enable input 3 SO Active-low Hall-effect switch output 4 LA LED anode (+) connection 5 FADE Fade-in/fade-out timing control 6 IREF Current reference resistor connection 7 POL Selects LED activation polarity relative to SO 8 GND Ground reference PAD Exposed thermal pad (may be left floating or tied to ground) – Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 3 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 ELECTRICAL CHARACTERISTICS: Valid at TA = –40°C to 125°C (Range K); TA = –40°C to 85°C (Range E); VIN = 7 to 24 V (unless otherwise specif ied) Characteristic Symbol Test Conditions Min. Typ. [1] Max. Units Operating, TJ < 165°C 7 – 24 V LED off, EN = high – 25 50 µA LED off, EN = high, see Figure 13 – 20 45 µA ILA = 0 mA, EN = low, see Figure 13 – 4 6 mA Measured from VIN > 7 V to ILA > 90% of 150 mA with POL = GND, EN = low, RIREF = 600 Ω, FADE disabled (see Fade pin description below) – – 1 ms Measured from EN < VIL to ILA > 90% of 150 mA with VIN > 7 V, RIREF = 600 Ω, FADE disabled (see Fade pin description below) – 50 – µs IIN(ACT) = 6.5 mA, TA = 25°C 32 45 – V See Figure 13 – 50 – ms – 50 – µs SUPPLY and STARTUP VIN Functional Operating Range VIN Average Current VIN Quiescent Current VIN Active Current Startup Time VIN (VDD) IINAVG IINQ IIN(ACT) tON External Response Time Supply Zener Clamp Voltage tEXT_ON VIN(Z) MICROPOWER OPERATION Period tPERIOD Awake Time tAWAKE LED CURRENT REGULATION Reference Voltage VIREF 267 µA < IREF < 2 mA – 1.2 – V Reference Current Ratio GH ILA ÷ IREF – 75 – – Current Accuracy [2][3][4] EILA 4.5 kΩ > RIREF > 600 Ω –5 – 5 % Output Source Current ILA RIREF = 600 Ω, LED driver enabled (see Table 1) – 150 170 mA VIN – VLA , ILA = 150 mA – – 2.4 V VIN – VLA , ILA = 75 mA – 800 – mV Current rising or falling between 10% and 90%, Fade disabled (see Fade pin description below) – 10 – µs Dropout Voltage VDO Current Slew Time tFADE(MIN) EN AND POL INPUTS EN Input Logic-Low Voltage VIL(EN) – – 0.8 V EN Input Logic-High Voltage VIH(EN) 2 – – V –2 – 2 µA 0 – 100 % EN Input Current ILOGIC-IN(EN) PWM Duty Cycle [5][6] PWM Frequency Range [5] PWM Input Voltage POL Input Logic-Low Voltage POL Average Leakage Current DC PWM applied to EN; 0 V ≤ VPWM ≤ 5.25 V fPWM PWM applied to EN; 0 V ≤ VPWM ≤ 5.25 V 0 – 1 kHz VPWM PWM applied to EN 0 – 5.25 V – – 0.8 V POL = GND – 80 – nA VIL(POL) ILOGIC-IN(POL) Continued on next page... Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 4 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 ELECTRICAL CHARACTERISTICS (continued): Valid at TA = –40°C to 125°C (Range K); TA = –40°C to 85°C (Range E); VIN = 7 to 24 V (unless otherwise specif ied) Characteristic Symbol Test Conditions Min. Typ. [1] Max. Units SO, IOUT = 20 mA, B > BOP, POL = float – 180 500 mV LOGIC OUTPUTS Output On Voltage Output Current Limit VOUT(SAT) IOUTPUT(SINK)C SO, TJ < TJ(max) 30 – 60 mA tr SO, RL = 820 Ω, CS = 20 pF – 0.2 – µs Output Fall Time tf SO, RL = 820 Ω, CS = 20 pF – 0.1 – µs Power-On State POS Output Rise Time SO, POL = GND or POL = float HIGH – ANALOG INPUTS Input Voltage Range VINPUT IREF, FADE 0 – 5.5 V 1.2 – 1.8 V – 1 – mA VSChys – 350 – mV TJM – 130 – °C ΔISEN/ΔTJ – –3.25 – %/°C TJL – 150 – °C – 170 – °C – 15 – °C – 40 70 G –70 –40 – G 5 25 – G – –25 –5 G 5 15 25 G PROTECTION Short Detect Voltage VSCD Measured at LA Short Circuit Source Current ISCS Short present LA to GND Short Release Voltage Hysteresis Thermal Monitor Activation Temperature Thermal Monitor Slope Thermal Monitor Low Current Temperature Overtemperature Shutdown TJF Overtemperature Hysteresis TJhys MAGNETIC CHARACTERISTICS [7] Operate Point Release Point Hysteresis Temperature increasing BOPS BOPN BRPS BRPN BHYS |BFIELD| > |BOP| |BFIELD| < |BRP| |BOPX – BRPX| Typical data is at TA = 25°C and VIN = 12 V. Resistor tolerance is not included. 3 When EN = low, E ILA = 100 × [( | ILA | × RIREF / 90 ) – 1], with ILA in mA and RIREF in kΩ. 4 Current Accuracy cannot be guaranteed once the device is in Thermal Monitor Actuation Protection. 5 Guaranteed by design, not tested in production. 6 At high PWM input frequencies, the current slew time may not provide sufficient time for I LA to reach either the user-selected maximum current or minimum current as the duty cycle approaches 0% and/or 100%. See Dimming Frequency and Duty Cycle section. 7 Magnetic flux density, B, is indicated as a negative value for north-polarity magnetic fields, and is a positive value for south-polarity magnetic fields. 1 2 Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 5 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 THERMAL CHARACTERISTICS Characteristic Symbol Test Conditions RθJA (High-K) JEDEC Package MS-012 BA. Test is performed using a high thermal conductivity, multilayer printed circuit board that approximates those specified in the JEDEC standards JESD51-7. Thermal vias are included per JESD51-5. See Figure 2 for more detail. RθJA (Usual-K) JEDEC Package MS-012 BA. Multiple measurement points on both single- and dual-layer printed circuit boards with minimal exposed copper (2-oz) area. See Figure 2 for more detail. Thermal Resistance (Junction to Ambient) Value Units 35 °C/W 62-147 °C/W Package Thermal Resistance (ºC/W) 200 One-sided board Two-sided board 150 • All copper is 2 oz. thickness • Area of copper refers to individual test locations on PCB 100 50 0 0.2 0.4 0.6 2 Area of Copper, One Side (in ) 0.8 Figure 2: Thermal Resistance (RθJA) versus Copper Area on Printed Circuit Board (PCB) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 6 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 CHARACTERISTIC PERFORMANCE Output On Voltage (VOUT(SAT) v. VIN) 7V 12 V 18 V 24 V -50 0 50 100 150 Output On Voltage, VOUT(SAT) (mV) Output On Voltage, VOUT(SAT) (mV) Output On Voltage (VOUT(SAT) v. TA) 500 450 400 350 300 250 200 150 100 50 0 500 450 400 350 300 250 200 150 100 50 0 -40°C 25°C 125°C 0 5 10 Ambient Temperature, TA (°C) 5 5 4 7V 2 12 V 18 V 1 24 V 0 25 30 4 3 -40°C 2 25°C 1 125°C 0 -50 0 50 100 150 0 5 Ambient Temperature, TA (°C) VIN Average Current (IINAVG v. TA) 7V 12 V 7V 18 V 12 V 24 V 18 V 0 0 50 Ambient Temperature, TA (°C) 50 Ambient Temperature, TA (°C) 15 20 25 30 VIN Average Current (IINAVG v. VIN) 100 100 24 V150 150 VIN Current, IIN (µA)IIN (µA) VIN Current, 50 45 50 40 45 35 40 30 35 25 30 20 25 15 20 10 155 100 5 -50 0 -50 10 Supply Voltage, VIN (V) VIN Average Current (IINAVG v. TA) VIN Current, IIN (µA)IIN (µA) VIN Current, 20 VIN Active Current (IIN(ACT) v. VIN) 6 VIN Current, IIN (mA) VIN Current, IIN (mA) VIN Active Current (IIN(ACT) v. TA) 6 3 15 Supply Voltage, VIN (V) 50 45 50 40 45 35 40 30 35 25 30 20 25 15 20 10 155 100 5 0 0 0 VIN Average Current (IINAVG v. VIN) -40°C 25°C -40°C 125°C 25°C 125°C 5 5 10 10 15 20 Supply Voltage, VIN (V) 15 20 25 30 25 30 Supply Voltage, VIN (V) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 7 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 VIN Quiescent Current (IINQ v. TA) VIN Quiescent Current (IINQ v. TA) 20 25 15 20 24 V 18 V 7V 12 V 10 15 105 0 30 35 25 30 25°C 125°C 18 V 24 V -50 0 -50 0 50 100 10 15 105 50 150 Ambient Temperature, TA (°C) 100 50 125°C 20 25 15 20 IN 12 V -40°C -40°C 25°C IN 7V 30 35 25 30 50 45 40 45 35 40 VIN Current, IIN (µA) V Current, I (µA) VIN Current, IIN (µA) VIN Current, IIN (µA) 45 40 45 35 40 VIN Quiescent Current (IINQ v. VIN) VIN Quiescent Current (IINQ v. VIN) 0 0 150 0 5 Ambient Temperature, TA (°C) Reference Voltage (VIREF v. TA) 12 V 1.25 18 V 1.2 24 V 1.15 1.1 1.05 Reference Voltage, VIREF (V) Reference Voltage, VIREF (V) 1.3 100 25°C 1.3 125°C 1.25 1.2 1.15 1.1 1.05 1 150 0 5 10 Ambient Temperature, TA (°C) 25 30 IREF = 0.267 mA 7V 22 12 V 21 18 V 20 24 V 19 18 17 100 150 Output Source Current, ILA (mA) Output Source Current, ILA (mA) 23 Ambient Temperature, TA (°C) 20 Output Source Current (ILA v. VIN) IREF = 0.267 mA 50 15 Supply Voltage, VIN (V) Output Source Current (ILA v. TA) 0 30 30 -40°C 1.35 1 -50 25 25 1.4 7V 50 20 Reference Voltage (VIREF v. VIN) 1.35 0 15 Supply Voltage, VIN (V) 1.4 -50 10 VIN (V) 10 Supply Voltage, 15 20 5 23 -40°C 22 25°C 21 125°C 20 19 18 17 0 5 10 15 20 25 30 Supply Voltage, VIN (V) For Output Source Current and Reference Current Ratio, the Thermal Monitor Activation is disabled during test. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 8 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 Output Source Current (ILA v. TA) Output Source Current (ILA v. VIN) 80 IREF = 1.0 mA 7V 12 V 78 18 V 76 24 V 74 72 70 -50 0 50 100 150 Output Source Current, ILA (mA) Output Source Current, ILA (mA) IREF = 1.0 mA 80 -40°C 78 25°C 76 125°C 74 72 70 0 5 Ambient Temperature, TA (°C) 7V 153 12 V 18 V 151 24 V 149 147 145 100 150 -40°C 153 25°C 151 125°C 149 147 145 0 5 10 25 30 IREF = 0.267 mA 7V 12 V 18 V 24 V 100 150 Reference Current Ratio, GH Reference Current Ratio, GH 85 83 81 79 77 75 73 71 69 67 65 50 20 Reference Current Ratio (GH v. VIN) IREF = 0.267 mA Ambient Temperature, TA (°C) 15 Supply Voltage, VIN (V) Reference Current Ratio (GH v. TA) 0 30 155 Ambient Temperature, TA (°C) -50 25 IREF = 2.0 mA Output Source Current, ILA (mA) Output Source Current, ILA (mA) 155 50 20 Output Source Current (ILA v. VIN) IREF = 2.0 mA 0 15 Supply Voltage, VIN (V) Output Source Current (ILA v. TA) -50 10 85 83 81 79 77 75 73 71 69 67 65 -40°C 25°C 125°C 0 5 10 15 20 25 30 Supply Voltage, VIN (V) For Output Source Current and Reference Current Ratio, the Thermal Monitor Activation is disabled during test. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 9 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 Dropout Voltage (VDO v. TA) Dropout Voltage (VDO v. ILA) VIN = 7 V VIN = 7 V 20 mA 4 50 mA 3 100 mA 150 mA 2 1 5 Dropout Voltage, VDO (V) Dropout Voltage, VDO (V 5 0 -40°C 4 25°C 3 125°C 2 1 0 -50 0 50 100 150 0 20 40 Ambient Temperature, TA (°C) Operate Point, South (BOPS v. TA) 80 100 120 140 160 Operate Point, South (BOPS v. VIN) 70 7V 60 12 V 50 18 V 40 24 V 30 20 10 Operate Point, BOPS (G) Operate Point, BOPS (G) 70 0 -40°C 60 25°C 50 125°C 40 30 20 10 0 -50 0 50 100 150 0 5 Ambient Temperature, TA (°C) 10 15 20 25 30 Supply Voltage, VIN (V) Release Point, South (BRPS v. TA) 70 Release Point, South (BRPS v. VIN) 70 7V 60 12 V 50 18 V 40 24 V 30 20 10 0 Release Point, BRPS (G) Release Point, BRPS (G) 60 Output Source Current, ILA (mA) -40°C 60 25°C 50 125°C 40 30 20 10 0 -50 0 50 Ambient Temperature, TA (°C) 100 150 0 5 10 15 20 25 30 Supply Voltage, VIN (V) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 10 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 Operate Point, North (BOPN v. TA) 0 7V -10 12 V -20 18 V -30 24 V -40 -50 -60 Operate Point, BOPN (G) Operate Point, BOPN (G) 0 Operate Point, North (BOPN v. VIN) -70 -40°C -10 25°C -20 125°C -30 -40 -50 -60 -70 -50 0 50 100 150 0 5 10 Ambient Temperature, TA (°C) Release Point, North (BRPN v. TA) 20 25 30 Release Point, North (BRPN v. VIN) 0 7V -10 12 V -20 18 V -30 24 V -40 -50 -60 Release Point, BRPN (G) Release Point, BRPN (G) 0 -70 -40°C -10 25°C -20 125°C -30 -40 -50 -60 -70 -50 0 50 100 150 0 5 10 Ambient Temperature, TA (°C) 12 V 18 V 24 V 50 Ambient Temperature, TA (°C) 100 150 Hysteresis, BHYS (G) 7V 0 20 25 30 Hysteresis (BHYS v. VIN) 25 23 21 19 17 15 13 11 9 7 5 -50 15 Supply Voltage, VIN (V) Hysteresis (BHYS v. TA) Hysteresis, BHYS (G) 15 Supply Voltage, VIN (V) 25 23 21 19 17 15 13 11 9 7 5 -40°C 25°C 125°C 0 5 10 15 20 25 30 Supply Voltage, VIN (V) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 11 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 FUNCTIONAL DESCRIPTION Overview Omnipolar Operation The APS13568 is an integrated Hall-effect switch with a linear current regulator which is designed to provide drive current and protection for a string of series connected high-brightness LEDs in automotive applications. It provides a single programmable current output sourcing up to 150 mA, with low dropout voltage. The integrated Hall-effect switch in the APS13568 is an omnipolar switch. The output switches when a magnetic field perpendicular to the Hall sensor exceeds the operate point threshold, BOPx (B > BOPS or B < BOPN). When magnetic field is reduced below the release point, BRPx (B < BRPS or B > BRPN), the device output goes to the other state. The output transistor is capable of sinking current up to the short-circuit current limit, IOM, which ranges from 30 to 60 mA. The difference in the magnetic operate and release points is the hysteresis, BHYS, of the device. This built-in hysteresis allows clean switching of the output even in the presence of external mechanical vibration and electrical noise. BHYS BHYS Increasing South Field Decreasing South Field Decreasing North Field Increasing North Field Increasing South Field Figure 3: Hall Switch Output (SO) State versus Magnetic Field (POL = float) Increasing North Field 0G Active Low 0G Active Low SW_OUT Increasing North Field Increasing South Field Decreasing North Field SW_OUT Decreasing South Field Pulled High Increasing North Field Pulled High BHYS BOPS BOPN BHYS BRPS Removal of the magnetic field results in an output state consistent with B < BRPx. Since the output state polarity relative to the magnetic thresholds is user-selectable via the POL pin, reference Table 1 to determine the expected output state. BOPS BRPS BRPN BOPN Current regulation is maintained and the LEDs are protected during a short to ground at any point in the LED string. A short to ground on the output terminal will disable the output until the short is removed. Integrated thermal management reduces the regulated current level at high internal junction temperatures to limit power dissipation. BRPN The APS13568 is designed for illumination applications where the LED activity is controlled by the integrated Hall-effect switch, external logic, or by a PWM input signal such as from an MCU (microcontroller). Increasing South Field Figure 4: Hall Switch Output (SO) State versus Magnetic Field (POL = GND) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 12 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 Pin Functions EN Active-low logic input to enable/disable the LED driver. VIN Table 2: LED Driver State Truth Table (EN) Supply to the micro-power control circuit and current regulator. A ceramic bypass capacitor, typically 100 nF, should be connected as close as possible to this pin and GND. See Figure 1 typical application circuit. SO Active-low open-drain output of the Hall-effect switch (requires pull-up resistor, RPU). The output polarity of SO depends on the configuration of the POL pin. See Figure 3 and Figure 4 and Table 1. Drives low when BFIELD > |BOP| when POL = float, or pulled high through a pull-up resistor on SO when POL = GND. POL Inverts SO polarity, as shown in Table 1. See Figure 3 and Figure 4. Table 1: SO State Truth Table (POL) POL GND Float BFIELD SO State |B| > |BOP| High |B| < |BRP| Low |B| > |BOP| Low |B| < |BRP| High POL should only be tied to ground or floated to achieve the desired output polarity. The LED driver is only enabled when the EN pin is pulled low. If SO is tied to EN, changing the SO polarity changes the behavior between LED off (POL = GND) and LED on (POL = Float) with a magnet present. EN State LED Driver State Low LED Driver Enabled; Device is in Active Mode High LED Driver Disabled; Device operates in Micropower Mode This provides direct on/off action and can be used for PWM control when the fade function is disabled. See FADE pin description below. Tie to SO for standalone APS13568 operation. FADE A capacitor between this pin and GND controls the turn-on and turn-off times of the LED current. To disable the fade feature, omit CFADE and float the FADE pin. IREF A 1.2 V reference used to set the LED current drive. Connect resistor RIREF to GND to set the reference current. See Equation 1. LA Current source output connected to the anode of the first LED in the string. GND Ground reference connection. This pin should be connected directly to the negative supply. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 13 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 PAD LED Current Level Isolated pad for thermal dissipation only. It may be left floating, but it is recommended to connect this pad to ground. The LED current is controlled by a linear current regulator between the VIN pin and the LA output. The basic equation that determines the nominal output current at this pin is: Given that the LED driver is enabled (see Table 1), ILA = Key POS Note: the output current may be reduced from the set level by the thermal monitor circuit. B > BOP (POL= GND) B < BRP(POL= Float) BRP< B < BOP Conversely, the reference resistor may be calculated from: POS SO VOUT(HIGH) VOUT(SAT ) RIREF = Output State Undefined for VIN < VIN(MIN) V VIN VREF × GH ILA (2) where ILA is in A, RIREF is in Ω, VREF = 1.2 V, and GH = 75. t VIN(MIN ) 0 (1) where ILA is in A and RIREF is in Ω; VREF × GH is 90. B < BRP(POL= GND) B > BOP (POL= Float) V VREF × GH RIREF tON t Figure 5: Power-On Timing For example, where the required current is 75 mA, the resistor value will be: 1.2 V × 75 (3) = 1.2 kΩ RIREF = 0.075 A It is important to note that because the APS13568 is a linear current regulator, the maximum regulated current is limited by the power dissipation and thermal management in the application. All current calculations assume an adequate heat sink and/or airflow for the power dissipated. The application section below provides further detail on thermal management and the associated limitations. Fade-In/Fade-Out Power-On Behavior Device power-on occurs once tON has elapsed. During the time prior to tON, and after VIN > VIN(min), the output state is high, regardless of the POL configuration. After tON has elapsed, the output will correspond with the applied magnetic field for B > BOP or B < BRP. See Figure 5 for an example. Powering-on the device in the hysteresis range (less than BOPx and greater than BRPx) causes the output state to be high. The correct state is attained after the first excursion beyond BOPx or BRPx. Fade timing is controlled by external capacitor, CFADE, on the FADE pin. A larger capacitor will result in a longer fade time. The 10%-90% fade time is approximated by the equation: tFADE = CFADE × 0.8 × 106 (4) where tFADE is in seconds and CFADE is in farads. Fade-in is triggered when the LED driver is enabled and fade-out is triggered when the LED driver is disabled (see Table 1). To disable the fade feature, omit CFADE and float the FADE pin. Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 14 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 VIN LA Any LED cathode short to ground. Current remains regulated in non-shorted LEDs. VIN LA Shorted output is disabled. Low current is sourced to detect when short is cleared. APS13568 APS13568 GND GND Figure 7: Output Short to Ground Figure 6: Any Cathode Short to Ground VIN LA APS13568 Only shorted LED(s) is(are) inactive. Current remains regulated in non-shorted LED(s). GND Figure 8: Shorted LED(s) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 15 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 Dimming Frequency and Duty Cycle Dimming of the LED can be controlled by applying a pulsewidth-modulated (PWM) signal to the EN pin (see Table 2). The duty cycle of the PWM directly correlates to the duty cycle of the LED current, provided that the fade function is disabled (see Fade pin description above). This controls the relative LED on-time versus off-time and changes the perceived brightness of the LED. The EN pin is rated for the full range of VIN and therefore when tied directly to the SO pin, VIN can be used as the pull-up supply for SO. EN tEXT_ON x– ILA (user-set level) When using the PWM capabilities, the PWM input voltage (VPWM) applied to the EN pin should be in the range of 0 to 5.25 V. The EN input has typical TTL switching thresholds, but exceeding 5.25 V may cause pulse-width (duty-cycle) distortion. The PWM input frequency (fPWM) can be as high as 1 kHz. 0– Figure 9: Low PWM Duty Cycle The combination of the external response time (tEXT_ON) and ILA current slew time (tFADE) may not provide sufficient time for the desired/user-set LA on and off current levels to be reached when EN is pulsed with short on/off times. See Figure 9 and Figure 10. EN This only affects the proportionality between the input PWM duty cycle on EN and LA duty cycle (and therefore average LA current) at higher PWM carrier frequencies in conjunction with very low or very high duty cycle (see Figure 11). ILA x– (user-set level) Figure 11 shows that with 100 Hz PWM frequency, all duty cycles from 0% to 100% are capable of producing an output current equal to the user-set ILA level. However, at 1 kHz PWM frequency, duty cycles from 95% to 100% produce an output which does not reach the user-set ILA current. The user’s PWM algorithm can adjust the duty cycle range accordingly. For example, with a PWM frequency of 1 kHz and duty cycle of 1% or 99%, the EN on time is 1% × 1 kHz = 10 μs. The external response time (tEXT_ON) and ILA current slew time (tFADE) is 50 μs (typ) + 10 μs (typ). 0– Figure 10: High PWM Duty Cycle LED Constant On 100 Safety Features The circuit includes several features to ensure safe operation and to protect the LEDs and the APS13568: • The current regulator between VIN and LA output provide a natural current limit due to the regulation. • The LA output includes a short-to-ground detector that will disable the output to limit the dissipation. • The thermal monitor reduces the regulated current as the temperature rises. • Thermal shutdown completely disables the outputs under extreme overtemperature conditions. LA Duty Cycle (%) fPWM = 100 Hz fPWM = 1000 Hz 0 0 LED Constant EN PWM Duty Cycle (%) 100 Off Figure 11: LA Duty Cycle vs. EN PWM Duty Cycle Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 16 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 SHORT-CIRCUIT DETECTION A short to ground on an LED cathode as in Figure 6 will not result in a short-to-ground fault condition. The current through the remaining LEDs will remain in regulation and the LEDs will be protected. If the LA output is pulled below the short detect voltage as in Figure 7, it will disable the driver output. A small current will be sourced from the disabled output to monitor the short and detect when it is removed. When the voltage at LA rises above the short detect voltage, the driver will be re-enabled. A shorted LED or LEDs in a multi-LED string, as in Figure 8, will not result in a short fault condition. The current through the remaining LEDs will remain in regulation and the LEDs will be protected. Thermal protection will still operate normally in all described LED short-circuit conditions. Short-circuit detection is shut off to minimize power consumption when the LED driver is disabled. tored and the regulator will be re-activated when the temperature drops below the threshold provided by the specified hysteresis. Note that it is possible for the APS13568 to transition rapidly between thermal shutdown and normal operation. This can happen if the thermal mass attached to the exposed thermal pad is small and TJM is increased to close to the shutdown temperature. The period of oscillation will depend on TJM, the dissipated power, the thermal mass of any heatsink present, and the ambient temperature. By mounting the APS13568 in close proximity and on the same thermal substrate as the LEDs, this feature can also be used to limit the dissipation of the LEDs. Micropower Operation The temperature monitor function included in the APS13568 reduces the LED current as the silicon junction temperature increases (see Figure 12). As the junction temperature of the APS13568 increases, the regulated current level is reduced, reducing the dissipated power in the APS13568 and in the LEDs. The current is reduced from the 100% level at typically 3.25%/°C until the point at which the current drops to 25% of the full value, defined at TJL. Above this temperature, the current will continue to reduce at a lower rate until the temperature reaches the overtemperature shutdown threshold temperature, TJF. The built-in micropower control periodically activates the Hall switch circuitry for a short period of time (tAWAKE), and deactivates it for the remainder of the period (tPERIOD). The short duration awake state allows for sensor stabilization prior to sampling the Hall switch and latching the state on the SO output. If the SO output state is off (high), it is kept high during the sleep period; updates to the output from the off-state only occur at the end of the Active (tAWAKE) pulse. If the output state is on (low), the Hall switch circuitry will remain awake until the output switches back off. The IC’s supply current is not affected by the output state, provided the LED driver is disabled. The micropower control operates independently of the LED driver state. If EN is forced low by an external circuit, the device will also remain in the awake mode. If the chip temperature exceeds the overtemperature limit TJF, the driver will be disabled. The temperature will continue to be moni- At power-on, the APS13568 will sample a tAWAKE cycle before the first tSLEEP cycle. Relative Sense Current (%) Temperature Monitor and Thermal Protection 100 t PERIOD 90 80 t AWAKE TJM IIN(ACT) 60 Sleep 40 TJF 25 20 0 70 TJL 90 110 130 150 Junction Temperature, TJ (ºC) 170 Figure 12: Temperature Monitor Current Reduction IINQ Sample and Output Latched Figure 13: Micropower Timing Diagram Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 17 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 APPLICATION INFORMATION Power Dissipation The most critical design consideration when using a linear regulator such as the APS13568 is the power produced internally as heat and the rate at which that heat can be dissipated. There are three sources of power dissipation in the APS13568: dissipated in the APS13568 is the sum of the quiescent power, the reference power, and the power in the regulator: PD = PQ + PREG – PREF The power that is dissipated in the LEDs is: • The quiescent power to run the control circuits • The power in the reference circuit where VLED is the voltage across all LEDs in the string. • The power due to the regulator voltage drop QUIESCENT POWER The quiescent power is the product of the quiescent current (IINQ) and the supply voltage (VIN), and it is not related to the regulated current. The quiescent power (PQ) is therefore defined as: PQ = VIN × IINQ (5) REFERENCE POWER The reference circuit draws the reference current from the supply and passes it through the reference resistor to ground. The reference circuit power is the product of the reference current and the difference between the supply voltage and the reference voltage, typically 1.2 V. The reference power (PREF) is therefore defined as: PREF = (VIN – VREF ) × VREF RIREF (6) REGULATOR POWER In most application circuits, the largest dissipation will be produced by the output current regulator. The power dissipated the current regulator is simply the product of the output current and the voltage drop across the regulator. The regulator power the output is defined as: PREG = (VIN – VLED ) × ILED (7) Note that the voltage drop across the regulator (VREG) is always greater than the specified minimum dropout voltage (VDO). The output current is regulated by making this voltage large enough to provide the voltage drop from the supply voltage to the total forward voltage of all LEDs in series (VLED). The total power (8) PLED = VLED × ILED(9) From these equations (and as illustrated in Figure 12), it can be seen that, if the power in the APS13568 is not limited, then it will increase as the supply voltage increases while the power in the LEDs will remain constant. Dissipation Limits The thermal shutdown feature limits the power that can be dissipated by the APS13568. THERMAL SHUTDOWN If the thermal resistance from the APS13568 to the ambient environment is high, then the silicon temperature will rise to the thermal shutdown threshold and the LED current will be disabled. After the current is disabled the power dissipated will drop and the temperature will fall. When the temperature falls by the hysteresis of the thermal shutdown circuit, the driver will be re-enabled and the temperature will start to rise again. This cycle will repeat continuously until the ambient temperature drops or the APS13568 is switched off. The period of this thermal shutdown cycle will depend on several electrical, mechanical, and thermal parameters. Supply Voltage Limits In many applications, especially in automotive systems, the available supply voltage can vary over a two-to-one range, or greater when double battery or load dump conditions are taken into consideration. In such systems, is it necessary to design the application circuit such that the system meets the required performance targets over a specified voltage range. To determine this range when using the APS13568, there are two limiting conditions: • For maximum supply voltage, the limiting factor is the power that can be dissipated from the regulator without exceeding the Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 18 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 temperature at which the thermal foldback starts to reduce the output current below an acceptable level. PD(MAX) = • For minimum supply voltage, the limiting factor is the maximum dropout voltage of the regulator, where the difference between the load voltage and the supply is insufficient for the regulator to maintain control over the output current. Minimum Supply Limit: Regulator Saturation Voltage The supply voltage (VIN) is always the sum of the voltage drop across the high-side regulator (VREG) and the forward voltage of the LEDs in the string (VLED). VLED is constant for a given current and does not vary with supply voltage. Therefore, VREG provides the variable difference between VLED and VIN. VREG has a minimum value below which the regulator can no longer be guaranteed to maintain the output current within the specified accuracy. This level is defined as the regulator dropout voltage (VDO). The minimum supply voltage, below which the LED current does not meet the specified accuracy, is therefore determined by the sum of the minimum dropout voltage (VDO) and the forward voltage of the LEDs in the string (VLED). The supply voltage must always be greater than this value and the minimum specified supply voltage, that is: VIN > VDO + VLED and VIN > VIN(MIN) (10) As an example, consider a string of two white LEDs, running at 150 mA, with each LED forward voltage at 3.15 V. The minimum supply voltage will be approximately: VIN(MIN) = 0.8 + (2 × 3.15) = 7.1 V The maximum power dissipation is defined as: (11) Maximum Supply Limit: Thermal Limitation As described above, when the silicon temperature reaches the thermal shutdown threshold the thermal protection feature causes the output current to be disabled. The maximum supply voltage is therefore defined as the voltage above which the LED current drops below the acceptable minimum. This can be estimated by determining the maximum power that can be dissipated before the internal (junction) temperature of the APS13568 reaches the thermal shutdown threshold. T(MAX) RJA (12) where ΔT(MAX) is the difference between the thermal protection activation temperature of the APS13568 and the maximum ambient temperature TA(max), and RθJA is the thermal resistance from the internal junctions in the silicon to the ambient environment. Thermal Dissipation The amount of heat that can pass from the silicon of the APS13568 to the surrounding ambient environment depends on the thermal resistance of the structures connected to the APS13568. The thermal resistance (RθJA) is a measure of the temperature rise created by power dissipation and is usually measured in degrees Celsius per watt (°C/W). The temperature rise (ΔT) is calculated from the power dissipated (PD) and the thermal resistance (RθJA) as: ΔT = PD × RθJA (13) A thermal resistance from silicon to ambient (RθJA) of approximately 35°C/W can be achieved by using a high thermal conductivity, multilayer printed circuit board as specified in the JEDEC standards JESD51-7 for JEDEC Package MS-012 BA (including thermal vias as called out in JESD51-5). Additional improvements may be achieved by optimizing the PCB design. Optimizing Thermal Layout The features of the printed circuit board, including heat conduction and adjacent thermal sources such as other components, have a significant effect on the thermal performance of the device. To optimize thermal performance, the following should be taken into account: • Maximizing the forward voltage of the LEDs relative to the VIN of the APS13568 will greatly reduce the power dissipated in the APS13568 by reducing the voltage drop across the APS13568. • The APS13568 exposed thermal pad should be connected to as much copper area as is available. This copper area may be left floating or connected to ground if desired. • Copper thickness should be as high as possible (for example, 2 oz. or greater for higher power applications). • The greater the quantity of thermal vias, the better the Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 19 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 dissipation. If the expense of vias is a concern, studies have shown that concentrating the vias directly under the device in a tight pattern, as shown in Figure 14, has the greatest effect. • Additional exposed copper area on the opposite side of the board should be connected by means of thermal vias. The copper should cover as much area as possible. • Other thermal sources should be placed as far away from the device as possible. Signal Traces LJ Package Outline LJ Package Exposed Thermal Pad Top Layer Exposed Copper 0.7 mm Ø 0.3 mm Via 0.7 mm Figure 14: Suggested PCB Layout for Thermal Optimization (Maximum available bottom-layer copper recommended) Extensive applications information for Hall effect devices is available in: • Hall-Effect IC Applications Guide (AN27701) • Allegro Hall-Effect Sensor ICs (AN296065) • Soldering Methods for Allegro’s Products — SMD and Through-Hole (AN26009) • Integrating Hall-Effect Magnetic Sensing Technology into Modern Household Appliances (AN295046) • Guidelines for Designing Subassemblies Using Hall-Effect Devices (AN27703.1) • Omnipolar Switch Hall-Effect IC Basics (AN296070) • Handling, Storage and Shelf Life of Semiconductor Devices (AN296126) All are provided on the Allegro website, www.allegromicro.com. • Chemical Exposure of Devices (AN295047) Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 20 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 PACKAGE OUTLINE DRAWING For Reference Only – Not for Tooling Use (Reference MS-012BA) Dimensions in millimeters – NOT TO SCALE Dimensions exclusive of mold flash, gate burrs, and dambar protrusions Exact case and lead configuration at supplier discretion within limits shown 4.90 ±0.10 8 8 1.75 0.25 0.17 D E1 B A 1.27 0.65 8° 0° 3.30 NOM 2.41 NOM 3.90 ±0.10 6.00 ±0.20 2.41 5.60 1.04 REF 1 2 Hall Element 0.115 mm left from center 0.25 BSC Branded Face 8X 0.10 C 0.51 0.31 1.27 BSC 1.70 MAX 0.15 0.00 C SEATING PLANE 1 1.27 0.40 2 3.30 C PCB Layout Reference View SEATING PLANE GAUGE PLANE A Terminal #1 mark area B Exposed thermal pad (bottom surface) C Reference land pattern layout (reference IPC7351 SOIC127P600X175-9AM); all pads a minimum of 0.20 mm from all adjacent pads; adjust as necessary to meet application process requirements and PCB layout tolerances; when mounting on a multilayer PCB, thermal vias at the exposed thermal pad land can improve thermal dissipation (reference EIA/JEDEC Standard JESD51-5) D Hall element (E1) centered in package (not to scale). Figure 15: Package LJ, 8-Pin SOICN with Exposed Thermal Pad Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 21 LED Driver with Integrated Micropower Hall-Effect Switch APS13568 Revision History Number Date – March 13, 2017 Description Initial release Copyright ©2017, Allegro MicroSystems, LLC Allegro MicroSystems, LLC reserves the right to make, from time to time, such departures from the detail specifications as may be required to permit improvements in the performance, reliability, or manufacturability of its products. Before placing an order, the user is cautioned to verify that the information being relied upon is current. Allegro’s products are not to be used in any devices or systems, including but not limited to life support devices or systems, in which a failure of Allegro’s product can reasonably be expected to cause bodily harm. The information included herein is believed to be accurate and reliable. However, Allegro MicroSystems, LLC assumes no responsibility for its use; nor for any infringement of patents or other rights of third parties which may result from its use. For the latest version of this document, visit our website: www.allegromicro.com Allegro MicroSystems, LLC 115 Northeast Cutoff Worcester, Massachusetts 01615-0036 U.S.A. 1.508.853.5000; www.allegromicro.com 22