IS32LT3175N/P SINGLE CHANNEL LINEAR LED DRIVER WITH FADE IN/OUT AND PWM DIMMING July 2016 GENERAL DESCRIPTION FEATURES The IS32LT3175 is a single channel linear programmable current regulator capable of up to 150mA. It integrates a debounce and latch circuit on the channel enable pin (EN) to facilitate the use of a low cost momentary contact switch. The PWM pin can be interfaced to a logic level “courtesy light” signal to directly drive the LED channel. The IS32LT3175P accepts a positive polarity PWM signal while the IS32LT3175N accepts a negative polarity PWM signal. The device operates as a stand-alone LED driver configurable with external resistors; no microcontroller is required. A single external resistor programs the current level, while two separate resistors independently program the fade in and fade out ramp rate for the channel. The device integrates a 63 steps fade in and fade out algorithm (Gamma correction) which causes the output LED current to gradually ramp up to the full source value after the EN pin is pulsed. The same controller causes the LED current to gradually ramp down to zero if the EN pin is pulsed while the output channel is ON. The fade ramp can be interrupted mid-cycle before completion of the ramp cycle. The EN pin will accept either a momentary contact switch or logic level signal pulsed low. The IS32LT3175 is targeted at the automotive market with end applications to include map and dome lighting as well as exterior accent lighting. For 12V automotive applications the low dropout driver can support 1 to 3 LEDs (VF = 3.2V) per channel. It is offered in a small thermally enhanced SOP-8-EP package. Operating voltage 5V to 42V Single channel current source - Programmable current via a single external resistor - Configurable from 20mA to 150mA Momentary contact button EN input - Input is debounced and latched - Higher priority than PWM input - Gamma corrected Fade In/Out algorithm - Pull down resistors set independent fade IN and OUT ramp time PWM input pin driven by external PWM source - PWM directly drives the current source - IS32LT3175P – Positive polarity - IS32LT3175N – Negative polarity Fault Protection: - OUT pin shorted to GND - ISET pin shorted to GND - Over temperature SOP-8-EP package Automotive Grade: - IS32LT3175P – AEC-Q100 - IS32LT3175N – AEC-Q100 Operating temperature range from -40°C ~ +125°C APPLICATIONS Automotive Interior: - Map/Dome light - Puddle lamp in doors - Glove box - Vanity mirror TYPICAL APPLICATION CIRCUIT Figure 1 Typical Application Circuit Note: The resistor RPWM is a fixed value. Please don’t change it. CPWM is optional. Add it for robust electromagnetic susceptibility. Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 1 IS32LT3175N/P PIN CONFIGURATION Package Pin Configuration (Top view) SOP-8-EP PIN DESCRIPTION No. Pin Description 1 EN Internally debounced input pin for control of LED current. A negative going pulse on this pin will toggle the state of the OUT current. The pin condition is constantly monitored after the debounce time period. 2 ISET Output current setting for channel. Connect a resistor between this pin and GND to set the maximum output current. 3 TSET_UP Timing control for the Fade In feature. Connect a resistor between this pin and GND to set the Fade In time. Connect this pin directly to ground to disable the fade function for instant ON. 4 TSET_DN Timing control for the Fade Out feature. Connect a resistor between this pin and GND to set the Fade Out time. Connect this pin directly to ground to disable the fade function for instant OFF. 5 GND Ground pin for the device. 6 OUT Output current source channel. 7 VCC Power supply input pin. A capacitor on this pin will help maintain EN latch status during low voltage conditions. PWM PWM (or BCM) signal via a 10kΩ to drive OUT pin. Pin condition is ignored if EN pin has latched and activated OUT pin. IS32LT3175P positive polarity, IS32LT3175N negative polarity. Thermal Pad Connect to GND. 8 Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 2 IS32LT3175N/P ORDERING INFORMATION Automotive Range: -40°C to +125°C Order Part No. Package QTY/Reel IS32LT3175P-GRLA3-TR IS32LT3175N-GRLA3-TR SOP-8-EP, Lead-free 2500 Copyright © 2016 Integrated Silicon Solution, Inc. All rights reserved. ISSI reserves the right to make changes to this specification and its products at any time without notice. ISSI assumes no liability arising out of the application or use of any information, products or services described herein. Customers are advised to obtain the latest version of this device specification before relying on any published information and before placing orders for products. Integrated Silicon Solution, Inc. does not recommend the use of any of its products in life support applications where the failure or malfunction of the product can reasonably be expected to cause failure of the life support system or to significantly affect its safety or effectiveness. Products are not authorized for use in such applications unless Integrated Silicon Solution, Inc. receives written assurance to its satisfaction, that: a.) the risk of injury or damage has been minimized; b.) the user assume all such risks; and c.) potential liability of Integrated Silicon Solution, Inc is adequately protected under the circumstances Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 3 IS32LT3175N/P ABSOLUTE MAXIMUM RATINGS VCC, OUT, PWM EN, ISET, TSET_UP, TSET_DN Ambient operating temperature, TA=TJ Maximum continuous junction temperature, TJ(MAX) Storage temperature range, TSTG Maximum power dissipation, PDMAX ESD (HBM) ESD (CDM) -0.3V ~ +45V -0.3V ~ +7.0V -40°C ~ +125°C 150°C -55°C ~ +150°C 1.96W ±2kV ±750V Note: Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only and functional operation of the device at these or any other condition beyond those indicated in the operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. THERMAL CHARACTERISTICS Characteristic Test Conditions Value Package Thermal Resistance (Junction to Ambient), θJA Package Thermal Resistance (Junction to Pad), θJP On 4-layer PCB based on JEDEC standard at 1W, TA=25°C 50.98°C/W 2.24°C/W ELECTRICAL CHARACTERISTICS TJ = -40°C ~ +125°C, VCC=12V, refer to each condition description. Typical values are at TJ = 25°C. Symbol Parameter VCC Supply voltage range VDO Minimum dropout voltage Condition tON Quiescent supply current Startup time IOUT_LIM Output limit current IOUT Output current (Note 3) EOUT Absolute current accuracy (Note 3) Typ. 5 Max. Unit 42 V VCC –VOUT, IOUT= -150mA (Note 1) 900 mV VCC –VOUT, IOUT= -100mA (Note 2) 700 mV 1 mA PWM pin floating. EN disables the output. ICC Min. 0.1 RISET=15kΩ, EN enable the output, PWM floating, OUT floating 2.3 3.8 mA VCC=4.2V, EN enable the output. VPWM=4V for IS32LT3175P and VPWM=GND for IS32LT3175N. 0.25 0.6 mA 400 μs VCC> 6V to IOUT<-5mA (Note 4) VCC –VOUT =1V, OUT sourcing current, ISET pin connected to GND. -240 -205 -160 mA RISET = 15kΩ, VCC –VOUT =1V,-40°C<TJ<+125°C -105 -100 -95 mA -50mA≤IOUT≤-20mA, VCC –VOUT =1V, -40°C< TJ <+125°C -8 8 % -150mA≤IOUT<-50mA, VCC –VOUT =1V, -40°C< TJ <125°C -6 6 % gLINE Output current line regulation IOUT = -50mA, 6V<VCC<18V, VOUT = VCC -2V (Note 4) -0.2 0.2 mA/V gLOAD Output current load regulation 2.5V< VOUT <VCC-2.0V,IOUT = -50mA (Note 4) -0.2 0.2 mA/V Current slew time Current rise/fall between 0%~100%, VTSET = 0V 70 100 μs PWM current latency Delay time between PWM rising edge to 10% of IOUT 10 17 μs tSL tTD_ON Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 45 4 IS32LT3175N/P ELECTRICAL CHARACTERISTICS (CONTINUE) TJ = -40°C ~ +125°C, VCC=12V, the detail refer to each condition description. Typical values are at TJ = 25°C. Symbol UVLO Parameter Release from under voltage lock out VCC voltage Condition Min. VCC rising release from UVLO Into under voltage lock out VCC VCC falling into UVLO voltage 4.1 Typ. Max. Unit 4.6 4.8 V 4.5 4.7 V Logic Input TSET_UP, TSET_DN VTSET Voltage reference TACC Fade timing accuracy 1 *Neglecting the RTSET Tolerance* RTSET_UP=100kΩ, TJ = 25°C -5 V 5 % 0.8 V Logic Input PWM – Active High (IS32LT3175P) VIL Input low voltage VIH Input high voltage VIN_HY Input hysteresis IPD Internal pull-down current 2 V (Note 4) 150 350 VPWM=12V 15 28 mV 46 μA 0.8 V Logic Input PWM – Active Low (IS32LT3175N) VIL Input low voltage VIH Input high voltage VIN_HY Input hysteresis IPU Internal pull-up current 2 V (Note 4) 150 350 VPWM=GND 20 38 mV 58 μA 0.8 V Logic Input EN VIL Input low voltage VIH Input high voltage VIN_HY Input hysteresis 2 (Note 4) 150 V 350 mV 50 kΩ RPU Internal pull-up resistor (Note 4) IPU Internal pull-up current VEN=0 55 75 95 μA tSW EN input debounce time EN pin must not change state within this time to be interpreted as a switch press or release 25 37 50 ms Measured at OUT 1.2 1.8 V Protection VSCD Short detect voltage VSCD_HY Short detect voltage hysteresis Measured at OUT 220 mV tFD Fault detect persistence time (Note 4) 5 ms TRO Thermal roll off threshold (Note 4) 145 °C TSD Thermal shutdown threshold Temperature increasing (Note 4) 175 °C THY Over temperature hysteresis Recovery = TSHT – TJ_HY (Note 4) 30 °C Note 1: IOUT output current in case of VCC-Vout=VDO called IOUT_VDO. IOUT output current in case of VCC-VOUT=2V called IOUT_VDO2V, VDO accuracy is computed as |IOUT_VDO-IOUT_VDO2V|/IOUT_VDO2V<5%. Note 2: IOUT output current in case of VCC-VOUT=VDO called IOUT_VDO. IOUT output current in case of VCC-VOUT=1V called IOUT_VDO1V, VDO accuracy is computed as |IOUT_VDO-IOUT_VDO1V|/IOUT_VDO1V<5%. Note 3: Output current accuracy is not intended to be guaranteed at output voltages less than 1.8V. Note 4: Guaranteed by design. Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 5 IS32LT3175N/P TYPICAL PERFORMANCE CHARACTERISTICS 3 200 RTSET = 100kΩ RISET = 15kΩ No Load 2 Output Current (mA) Supply Current (mA) 2.5 RTSET = 100kΩ VDO = 1V Operating Mode 1.5 Shutdown Mode 1 150 RISET = 15kΩ 100 50 RISET = 75kΩ 0.5 0 5 10 15 20 25 30 35 40 0 5 45 RISET = 10kΩ 10 15 Supply Voltage (V) 30 Output Current (mA) 100 50 0 45 VCC = 12V RISET = 15kΩ RTSET = 0Ω PWM Frequency is 50Hz,100Hz,300Hz 80 60 40 20 10 50 100 150 0 200 0 20 40 Figure 4 60 80 100 Duty Cycle (%) RISET (kΩ) Output Current vs. RISET Figure 5 Output Current vs. PWM Duty Cycle 2000 2000 VCC = 12V RISET = 20kΩ RISET = 20kΩ RTSET = 600kΩ RTSET = 600kΩ 1500 1500 1000 Fade Time (ms) Fade Time (ms) 40 100 VCC = 12V RTSET = 100kΩ VDO = 1V TJ = 25°C 150 RTSET = 300kΩ 500 0 35 Output Current vs. Supply Voltage Figure 3 200 Output Current (mA) 25 Supply Voltage (V) Supply Current vs. Supply Voltage Figure 2 20 10 15 20 RTSET = 300kΩ 500 RTSET = 100kΩ 5 1000 25 30 35 40 45 RTSET = 100kΩ 0 -40 -25 -10 Supply Voltage (V) Figure 6 Fade Time vs. Supply Voltage Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 5 20 35 50 65 80 95 110 125 Temperature (°C) Figure 7 Fade Time vs. Temperature 6 IS32LT3175N/P 200 3.5 VCC = 12V RTSET = 0Ω VDO = 1V Output Current (mA) Supply Current (mA) 3 VCC = 12V RTSET = 0Ω RISET = 15kΩ No Load 2.5 Operating Mode 2 1.5 Shutdown Mode 1 RISET = 10kΩ 150 RISET = 15kΩ 100 RISET = 30kΩ 50 RISET = 75kΩ 0.5 0 -40 -25 -10 5 20 35 50 65 80 95 110 125 0 -40 -5 30 Supply Current vs. Temperature Figure 9 PWM On Delay Time RTSET = 0Ω RISET = 15kΩ 135 175 Output Current vs. Temperature PWM Off Delay Time RTSET = 0Ω RISET = 15kΩ VV PWM EN 2V/Div VVPWM EN 2V/Div IOUT 50mA/Div IOUT 50mA/Div Time (10µs/Div) Time (10µs/Div) Figure 10 100 Temperature (°C) Temperature (°C) Figure 8 65 PWM On Delay Time (For IS32LT3175P Only) Figure 11 PWM On Delay Time (For IS32LT3175P Only) RTSET = 0Ω RTSET = 0Ω IOUT 20mA/Div IOUT 20mA/Div Time (20µs/Div) Time (20µs/Div) Figure 12 Instant on Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 Figure 13 Instant Off 7 IS32LT3175N/P Fade In RTSET = 100kΩ Fade Out RTSET = 100kΩ IOUT 20mA/Div IOUT 20mA/Div VEN 5V/Div VEN 5V/Div Time (100ms/Div) Figure 14 Time (100ms/Div) VEN vs. IOUT Figure 15 Fade In RTSET = 510kΩ VEN vs. IOUT Fade Out RTSET = 510kΩ IOUT 50mA/Div IOUT 50mA/Div VEN 5V/Div VEN 5V/Div Time (400ms/Div) Figure 16 Time (400ms/Div) VEN vs. IOUT Figure 17 Fade In RTSET = 510kΩ Enable Twice VEN vs. IOUT Fade Out RTSET = 510kΩ Enable Twice IOUT 50mA/Div IOUT 50mA/Div VEN 2V/Div VEN 2V/Div Time (400ms/Div) Figure 18 Time (400ms/Div) VEN vs. IOUT Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 Figure 19 VEN vs. IOUT 8 IS32LT3175N/P 200 Output Current (mA) RTSET = 0Ω TJ = 25°C RISET = 10kΩ 160 RISET = 15kΩ 120 80 RISET = 30kΩ 40 0 0 2000 4000 6000 8000 10000 Headroom Voltage (mV) Figure 20 Output Current vs. Headroom Voltage Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 9 IS32LT3175N/P FUNCTIONAL BLOCK DIAGRAM Note: IS32LT3175P does not invert the PWM input. Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 10 IS32LT3175N/P APPLICATION INFORMATION The IS32LT3175 is a single channel linear current driver optimized to drive an automotive interior LED map light, or other interior lamp which is frequently toggled between the In and Out condition. The device integrates a debounce input circuit to enable use of a low cost momentary contact switch for controlling In/Out an external LED. In addition, a programmable fade ramp timing function provides flexibility in setting different Fade In and Fade Out ramp duration periods. The fade ramp cycle can be interrupted mid-cycle before the ramp has completed, Figure 21. mA in the time period as programmed by the resistor (RTSET_DN) attached to the TSET_DN pin. ENx Debounce Time Debounce Time OUTx (On Condition) Fade In OUTx (Off Condition) Fade Out t Fade In Figure 22 Figure 21 Fade Ramp Interrupted Mid-cycle The regulated LED current (up to 150mA) is set by a single reference resistor (RISET). OUTPUT CURRENT SETTING A single programming resistor (RISET) controls the maximum output current for output channel simultaneously. The programming resistor may be computed using the following Equation (1): RISET 1500 I SET (1) (10kΩ≤RISET≤75kΩ) The device is protected from an output overcurrent condition caused by an accidental short circuit of the ISET pin, by internally limiting the maximum current in the event of an ISET short circuit to 205mA (Typ.). EN PIN OPERATION The EN pin has in integrated pull-up source so that no external components are required to provide the input high level to the pin. The output channel powers up in the ‘OFF’ condition. Toggling the EN pin from high to low for a period of time that exceeds the debounce time will cause the output to be toggled and latched from the OFF condition to the current source condition. When this happens, the output current gradually ramps up from zero mA to the programmed value (set by RISET) over the time set by the resistor (RTSET_UP) attached to the TSET_UP pin. Conversely, if it is already in the source condition, and the EN pin is toggled low, then the output current will begin to ramp down towards zero Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 EN Debounced Debounce – Output control is provided by a debounced switch input, providing an ON/OFF toggle action for various switch or button characteristics. An internal debounce circuit will condition the EN input signal so a single press of the mechanical switch doesn’t appear like multiple presses. The EN input is debounced by typically 37ms. Note: The debounce time applies to both falling and rising edges of the EN signal. FADE IN AND FADE OUT DIMMING The LED fade function can be accomplished in one of two methods; 1) by applying a PWM control signal to the PWM pin, or 2) when the EN pin is pulled low. PWM Dimming – The PWM pin can be driven by an external PWM signal source to accomplish LED dimming. The integrated gamma correction and fade IN/OUT ramp functions are disabled when actively driving the PWM pin. The PWM pin input is ignored if the LED channel was previously active due to the EN pin. The EN pin will override the PWM function; it can be used to toggle the LED channel from its previous state even though the PWM pin is active. The recommended PWM signal frequency range is 50Hz-300Hz. The duty cycle can be 0-100%. The output current of the PWM dimming is given by: I OUT 1500 DPWM RISET Where, DPWM is the duty cycle of the PWM. Please refer to Figure 10 and 11 for the delay time of PWM edge to current change edge. Figure 24 and 25 show the PWM polarity difference of IS32LT3175P and IS32LT3175N. 11 IS32LT3175N/P EN Dimming –The LED output current will gradually ramp up from zero to the final value as programmed by the resistor (RISET) connected to the ISET pin. The time period over which the ramping happens is determined by the resistor (RTSET_UP) connected to the TSET_UP pin for Fade In time and by resistor (RTSET_DN) connected to TSET_DN pin for Fade Out time. The output current will ramp up (or down) in 63 steps, with integrated gamma correction for an extremely visual linear lumen output of the LED. The ramp time can be interrupted mid-cycle each time the EN pin is pulled low. the EN latch status as long as the VCC pin voltage remains above 3.8V. An external capacitor (Figure 23) is necessary to help maintain the VCC pin voltage >3.8V and to supply current to the device status latch circuitry. However, should the voltage drop below 3.8V, the internal latch will be reset to the power on default status (LED initial off state). The current source will be turned ON when the input voltage is re-applied and the VCC pin rises above 4.6V (Typ.). The EN function has priority over the PWM function; if the LED has been turned on due to the EN function then the PWM dimming pin input is ignored. UNDERVOLTAGE LOCKOUT IS32LT3175N/P integrates an undervoltage lockout function to prevent mis-operation of the device during low input voltage conditions. Figure 23 Capacitor For Latch Status Should the VCC pin voltage fall below 4.5V (Typ.), the device will turn OFF the current source and maintain PWM Duty Cycle Ramp Up PWM High PWM Duty Cycle Ramp Down LED Full On PWM Low PWM Low LED Off LED Fade Out LED Fade In PWM Signal Input (Positive Polarity – IS32LT3175P) Figure 24 PWM High LED Off PWM Duty Cycle Ramp Up PWM Duty Cycle Ramp Down PWM High LED Off LED Off PWM Low LED Fade In Figure 25 LED Full On PWM Signal Input (Negative Polarity – IS32LT3175N) SETTING THE FADE TIME The fade time is set by two external programming resistors; RTSET_UP and RTSET_DN. The RTSET_UP connected to the TSET_UP pin configures the fade ramp ON time while the RTSET_DN connected to the TSET_DN pin configures the fade ramp out time. The fade time (In or Out) is programmable by Equation (2): t RTSET 2.5s LED Fade Out (2) Note: In order to get the optimized effect, the recommended fading time is between 1.5s (RTSET= 600kΩ) and 0.25s (RTSET= 100kΩ). If either the TSET_UP or TSET_DN pin is tied directly to GND, the corresponding fade function is canceled and the ramp time is about 70µs, or ‘instant on’. However, the debounce feature of the EN pin is not disabled. For example, RTSET=100kΩ, Fade In/Out time is about 0.25s. Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 12 IS32LT3175N/P 2500 900 800 LED Current Duty 2000 Fade Time (ms) 1000 VCC = 12V RISET = 15kΩ TJ = 25°C 1500 1000 500 700 600 500 400 300 200 100 0 100 200 400 600 800 1000 0 0 5 10 15 20 RTSET (kΩ) 30 35 40 45 50 55 60 62 Gamma Steps Fade Time vs. RTSET Figure 26 25 Figure 27 Gamma Correction(63 Steps) GAMMA CORRECTION FAULT DETECTION In order to perform a better visual LED breathing effect we recommend using a gamma corrected value to set the LED intensity. This results in a reduced number of steps for the LED intensity setting, but causes the change in intensity to appear more linear to the human eye. An output shorted to GND fault is detected if the output voltage on a channel drops below the low voltage threshold VSCD and remains below the threshold for tFD. The channel (OUT) with the short condition will reduce its output current to 20% of ISET. When the short condition is removed, the output current will recover to original value. Gamma correction, also known as gamma compression or encoding, is used to encode linear luminance to match the non-linear characteristics of display. Gamma correction will vary the step size of the current such that the fading of the light appears linear to the human eye. Even though there may be 1000 linear steps for the fading algorithm, when gamma corrected, the actual number of steps could be as low as 63. Table 1 63 Gamma Steps Correction C(0) C(1) C(2) C(3) C(4) C(5) C(6) C(7) 0 2 4 6 8 10 12 16 C(8) C(9) C(10) C(11) C(12) C(13) C(14) C(15) 20 24 28 32 36 42 48 54 C(16) C(17) C(18) C(19) C(20) C(21) C(22) C(23) 60 66 72 80 88 96 104 112 C(24) C(25) C(26) C(27) C(28) C(29) C(30) C(31) 120 130 140 150 160 170 180 194 C(32) C(33) C(34) C(35) C(36) C(37) C(38) C(39) 208 222 236 250 264 282 300 318 C(40) C(41) C(42) C(43) C(44) C(45) C(46) C(47) 336 354 372 394 416 438 460 482 C(48) C(49) C(50) C(51) C(52) C(53) C(54) C(55) 504 534 564 594 624 654 684 722 C(56) C(57) C(58) C(59) C(60) C(61) C(62) 760 798 836 874 914 956 1000 Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 When the ISET pin is shorted to GND and output current is larger than limit value, about 205mA, the output current will be clamped. Once the short fault condition is removed, the output current will recover to its original value. OVERTEMPERATURE PROTECTION The device features an integrated thermal rollback feature which will reduce the output current in a linear fashion if the silicon temperature exceeds 145°C (typical). In the event that the die temperature continues to increase, the device will enter thermal shutdown if the temperature exceeds 175°C. THERMAL ROLLOFF The output current will be equal to the set value as long as the die temperature of the IC remains below 145°C (Typical). If the die temperature exceeds this threshold, the output current of the device will begin to reduce at a rate of 3%/°C. The roll off slope is related to ISET value. When ISET=20mA, the roll off slope is about 3.7%. When ISET=150mA, the roll off slope is about 2.2%. THERMAL SHUTDOWN In the event that the die temperature exceeds 175°C, the output channel will go to the ‘OFF’ state. At this point, the IC presumably begins to cool off. Any attempt to toggle the channel back to the source condition before the IC cooled to < 145°C will be blocked and the IC will not be allowed to restart. 13 IS32LT3175N/P THERMAL CONSIDERATIONS The package thermal resistance, θJA, determines the amount of heat that can pass from the silicon die to the surrounding ambient environment. The θJA is a measure of the temperature rise created by power dissipation and is usually measured in degree Celsius per watt (°C/W). The junction temperature, TJ, can be calculated by the rise of the silicon temperature, ∆T, the power dissipation, PD, and the package thermal resistance, θJA, as in Equation (3): PD VCC I CC (VCC VLED ) I OUT The thermal resistance is achieved by mounting the IS32LT3175N/P on a standard FR4 double-sided printed circuit board (PCB) with a copper area of a few square inches on each side of the board under the IS32LT3175N/P. Multiple thermal vias, as shown in Figure 29, help to conduct the heat from the exposed pad of the IS32LT3175N/P to the copper on each side of the board. The thermal resistance can be reduced by using a metal substrate or by adding a heatsink or thicker copper plane. (3) and, TJ TA T TA PD JA (4) Where ICC is the IC quiescent current, VCC is the supply voltage, VLED is the voltage across VCC to OUT and TA is the ambient temperature. When operating the chip at high ambient temperatures, or when driving maximum load current, care must be taken to avoid exceeding the package power dissipation limits. The maximum power dissipation can be calculated using the following Equation (5): PD ( MAX ) (5) JA Vehicle electronics can be affected by electromagnetic interference (EMI) caused by ‘stray’’ magnetic and electric fields from automotive inductive load switching. Running throughout the vehicle are wiring harnesses which behave as ‘‘hidden antennas’’ and pickup these harmonic frequencies. So, 125C 25C 1.96W 50.98C / W Figure 28, shows the power derating of the IS32LT3175 on a JEDEC board (in accordance with JESD 51-5 and JESD 51-7) standing in still air. 2.5 SOP-8-EP Power Dissipation (W) Board Via Layout For Thermal Dissipation EMI AT THE CABLE AND INTERCONNECT LEVEL 125C 25C PD ( MAX ) Figure 29 2 Because the IS32LT3175 is usually connected with a long wire to the vehicle’s central computer, it could be susceptible to EMI transients. For example, a coupled EMI transient on the wiring harness connected to the IS32LT3175’s PWM pin 8 can be passed through and cause a slight LED flicker. 1 To avoid this, an RC low-pass filter can be implemented to attenuate high frequency signals at the PWM pin. The low-pass filter will allow only low frequency signals from 0Hz to its cut-off frequency (ƒc) to pass while attenuating frequencies above this cut-off frequency. 0.5 The formula to calculate the cut-off frequency of an RC filter is: 1.5 0 -40 fC -25 -10 5 20 35 50 65 80 95 110 125 Temperature (°C) Figure 28 Dissipation Curve Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 1 2 RPWM C PWM (6) As shown in Figure 30, typical values for RPWM=10kΩ and CPWM=3.3nF. For the IS32LT3175 the value of RPWM is fixed at 10kΩ (must always be installed) while CPWM is optional and its value can vary depending on the vehicle’s EMI environment. 14 IS32LT3175N/P 8 PWM 50Hz~300Hz RPWM 10k PWM CPWM 3.3nF IS32LT3175N/P Figure 30 fC RC filter for PWM EMI 1 4.7 kHz 2 10k 3.3nF Frequencies above 4.7kHz will be attenuated while frequencies below 4.7kHz will pass through without attenuation. Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 Figure 31 Low-pass filter gain-magnitude frequency response 15 IS32LT3175N/P CLASSIFICATION REFLOW PROFILES Profile Feature Pb-Free Assembly Preheat & Soak Temperature min (Tsmin) Temperature max (Tsmax) Time (Tsmin to Tsmax) (ts) 150°C 200°C 60-120 seconds Average ramp-up rate (Tsmax to Tp) 3°C/second max. Liquidous temperature (TL) Time at liquidous (tL) 217°C 60-150 seconds Peak package body temperature (Tp)* Max 260°C Time (tp)** within 5°C of the specified classification temperature (Tc) Max 30 seconds Average ramp-down rate (Tp to Tsmax) 6°C/second max. Time 25°C to peak temperature 8 minutes max. Figure 30 Classification Profile Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 16 IS32LT3175N/P PACKAGE INFORMATION SOP-8-EP Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 17 IS32LT3175N/P RECOMMENDED LAND PATTERN 1.27 1.75 2.41 3.3 5.6 0.65 Note: 1. Land pattern complies to IPC-7351. 2. All dimensions in MM. 3. This document (including dimensions, notes & specs) is a recommendation based on typical circuit board manufacturing parameters. Since land pattern design depends on many factors unknown (eg. User’s board manufacturing specs), user must determine suitability for use. Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 18 IS32LT3175N/P REVISION HISTORY Revision 0A 0B 0C A Detail Information Initial release 1. Update typical application circuit 2. Add UVLO description 3. Update Figure 24 and 25 1. Update functional block 2. Update EC table 3. Update Gamma Correction section 4. Update Figure 10 and 11 5. Update Automotive Grade 1. Update Typical Application Circuit with RC on PWM pin 2. Add description of PWM pin EMI considering 3. Update Automotive Grade Integrated Silicon Solution, Inc. – www.issi.com Rev.A, 07/19/2016 Date 2016.05.04 2016.03.31 2016.05.27 2016.07.19 19