LV5680NPVC-XH

LV5680NPVC Linear Voltage Regulator, Multiple-Output, System Power Supply IC, for Automotive Infotainment System Overview The LV5680NPVC is a multi-power supply system IC that provides four regulator outputs and two high side switches as well as a number of protection functions including overcurrent protection, overvoltage protection and overheat protection. It is an optimal power supply IC for car audio and car entertainment systems and similar products. Features • Four regulator output systems For microcontroller: 5.0V output voltage, 200mA maximum output current For CD drive: 8.0V output voltage, 1300mA maximum output current For illumination: 8 to 12V output voltage (output can be set with external resistors), 300mA maximum output current For audio systems: 8 to 9V output voltage (output voltage can be set with external resistors), 300mA maximum output current • Two VCC-linked high side switch systems EXT: 350mA maximum output current, 0.5V voltage difference between input and output. ANT: 300mA maximum output current, 0.5V voltage difference between input and output. • Two VDD 5V-linked high side switch systems SW5V: 200mA maximum output current, 0.2V voltage difference between input and output. ACC (accessory voltage detection output): 100mA maximum output current, 0.2V voltage difference between input and output. • Overcurrent protection function • Overvoltage protection function, typ 21V (excluding VDD 5V output) • Overheat protection function, typ 175ºC • On-chip accessory voltage detection circuit • P-channel LDMOS used for power output block (Warning) The protector functions only improve the IC’s tolerance and they do not guarantee the safety of the IC if used under the conditions out of safety range or ratings. Use of the IC such as use under over current protection range or thermal shutdown state may degrade the IC’s reliability and eventually damage the IC. www.onsemi.com HZIP15J GENERIC MARKING DIAGRAM XXXXXXXXXX YMDDD XXXXX = Specific Device Code Y = Year M = Month DDD = Additional Traceability Data ORDERING INFORMATION Ordering Code: LV5680NPVC-XH Package HZIP15J (Pb-Free / Halogen Free) Shipping (Qty / packing) 20 / Fan-Fold Typical Applications • Automotive infotainment © Semiconductor Components Industries, LLC, 2017 February 2017- Rev. 1 1 Publication Order Number: LV5680NPVC/D LV5680NPVC Specifications Absolute Maximum Ratings at Ta = 25C Parameter (Note 1) Conditions Conditions Ratings Supply voltage VCC max Peak supply voltage VCC peak See below for the waveform applied. Allowable Power dissipation Pd max Independent IC Unit 36 Ta  25C Al heat sink (Note 2) With an infinity heat sink V 50 V 1.5 W 5.6 W 32.5 W 150 C Junction temperature Tj max Operating ambient temperature Topr -40 to +85 C Storage temperature Tstg -55 to +150 C 1. Stresses exceeding those listed in the Maximum Rating table may damage the device. If any of these limits are exceeded, device functionality should not be assumed, damage may occur and reliability may be affected. 2. When the Aluminum heat sink (50mm  50mm  1.5mm) is used Recommended Operating Ranges at Ta = 25C Parameter Operating supply voltage 1 Operating supply voltage 2 (Note 3) Conditions Ratings VDD output, SW output, ACC output Unit 7.5 to 16 V ILM output at 10V 12 to 16 V ILM output at 8V 10 to 16 V Operating supply voltage 3 Audio output at 9V 10 to 16 V Operating supply voltage 4 CD output (CD output current = 1.3A) CD output (CD output current  1A) 10.5 to 16 V 10 to 16 V 3. Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond the Recommended Operating Ranges limits may affect device reliability. Electrical Characteristics at VCC = 14.4V, Ta = 25°C Parameter Current drain Symbol ICC (Note 4,10) Conditions Ratings min typ VDD no load, CTRL1/2 = L/L, ACC = 0V Unit max 400 800 A 0.5 V CTRL1 Input Low input voltage VIL1 0 M1 input voltage VIM11 0.8 1.1 1.4 V M2 input voltage VIM21 1.9 2.2 2.5 V High input voltage VIH1 2.9 3.3 5.5 V Input impedance RIH1 350 500 650 k 0.5 V 1.65 2.1 V CTRL2 Input Low input voltage VIL2 0 M input voltage VIM2 1.1 High input voltage VIH2 2.5 3.3 5.5 V Input impedance RIH2 350 500 650 k VDD 5V Output (Note 5) The VDD 5V output supplies the output currents of SW 5V and ACC 5V. Output voltage 1 VO1 IO1 = 200mA, IO7, IO8 = 0A 4.75 5.0 5.25 Output voltage 2 VO1’ IO1 = 200mA, IO7 = 200mA, IO8 = 100mA 4.75 5.0 5.25 Output total current Ito1 VO1  4.75V, Ito1 = IO1+IO7+IO8 500 Line regulation VOLN1 7.5V  VCC  16V, IO1 = 200mA (Note 6) 30 90 mV Load regulation VOLD1 1mA  IO1  200mA (Note 6) 70 150 mV Dropout voltage 1 VDROP1 IO1 = 200mA (Note 6) 1.0 1.5 V Dropout voltage 2 VDROP1’ IO1 = 100mA (Note 6) 0.7 1.05 V Dropout voltage 3 VDROP1” IO1+IO7+IO8 = 500mA 2.5 3.75 V Ripple rejection RREJ1 f = 120Hz, IO1 = 200mA (Note 6) 40 V V mA 50 dB Continued on next page. www.onsemi.com 2 LV5680NPVC Continued from preceding page. Parameter Symbol Conditions Ratings min typ Unit max CD Output ; CTRL2 = H Output voltage VO2 IO2 = 1000mA Output current IO2 VO2  7.6V Line regulation VOLN2 10.5V  VCC  16V, IO2 = 1000mA Load regulation VOLD2 Dropout voltage 1 VDROP2 Dropout voltage 2 VDROP2’ IO2 = 500mA Ripple rejection RREJ2 f = 120Hz, IO2 = 1000mA 7.6 8.0 8.4 1300 V mA 50 100 mV 10mA  IO2  1000mA 100 200 mV IO2 = 1000mA 1.0 1.5 V 0.5 0.75 V 40 50 dB 1.222 1.260 1.298 V AUDIO (8-9V) Output ; CTRL2 = M AUDIO_F pin voltage VI 3 AUDIO_F pin inflow current IIN3 1 A AUDIO output voltage 1 VO3 IO3 = 200mA, R2 = 30k, R3 = 5.6k (Note 7) 7.65 8.0 8.35 V AUDIO output voltage 2 VO3’ IO3 = 200mA, R2 = 27k, R3 = 4.7k (Note 7) 8.13 8.5 8.87 V AUDIO output voltage 3 VO3” IO3 = 200mA, R2 = 24k, R3 = 3.9k (Note 7) 8.6 9.0 9.4 AUDIO output current IO3 Line regulation VOLN3 10V  VCC  16V, IO3 = 200mA 30 90 mV Load regulation VOLD3 1mA  IO3  200mA 70 150 mV Dropout voltage 1 VDROP3 IO3 = 200mA 0.3 0.45 V Dropout voltage 2 VDROP3’ IO3 = 100mA 0.15 0.23 Ripple rejection RREJ3 f = 120Hz, IO3 = 200mA -1 300 V mA V 40 50 dB 1.222 1.260 1.298 V 11.4 12.0 12.6 V ILM (8-12V) Output ; CTRL1 = M1 ILM_F pin voltage VI4 ILM output voltage 1 VO4 IO4 = 200mA ILM output voltage 2 VO4’ IO4 = 200mA, R1 = 270k (Note 8) 8.5 10.0 11.5 V ILM output voltage 3 VO4” IO4 = 200mA, R1 = 100k (Note 8) 6.8 8.0 9.2 V ILM output current IO4 R1 = 270k 300 Line regulation VOLN4 12V  VCC  16V, IO4 = 200mA, R1 = 270k 30 90 mV Load regulation VOLD4 1mA  IO4  200mA 70 150 mV Dropout voltage 1 VDROP4 IO4 = 200mA 0.7 1.05 V 0.35 0.53 mA Dropout voltage 2 VDROP4’ IO4 = 100mA Ripple rejection RREJ4 f = 120Hz, IO4 = 200mA Output voltage VO5 IO5 = 350mA Output current IO5 VO5  VCC-1.0 Output voltage VO6 IO6 = 300mA Output current IO6 VO6  VCC-1.0 VO7 IO7 = 1mA, IO1, IO8 = 0A (Note 9) VO1-0.25 VO1 VO1-0.45 VO1-0.2 V 40 50 dB VCC-1.0 VCC-0.5 V Remoto (EXT) ; CTRL1 = M2 350 mA ANT remoto ; CTRL1 = H VCC-1.0 VCC-0.5 V 300 mA SW 5V Output ; CTRL2 = M Output voltage 1 Output voltage 2 VO7’ IO7 = 200mA, IO1, IO8 = 0A (Note 9) Output current IO7 VO7  4.55 V V 200 mA ACC Detection ; ACC Integration 5V output ACC detection voltage VTH8 2.8 3.0 3.2 Hysteresis width VHIS8 0.2 0.3 0.4 V V Input impedance ZI8 (Pull-down resistance internal) 42 60 78 k ACC output voltage 1 VO8 IO8 = 0.5mA, IO1, IO7 = 0A (Note 9) VO1-0.25 VO1 V ACC output voltage 2 VO8’ IO8 = 100mA, IO1, IO7 = 0A (Note 9) VO1-0.45 VO1-0.2 V VO8  4.55 100 mA 4. Functional operation above the stresses listed in the Recommended Operating Ranges is not implied. Extended exposure to stresses beyond the Recommended Operating Ranges limits may affect device reliability. ACC output voltage IO8 www.onsemi.com 3 LV5680NPVC 5. The VDD 5V output also supplies the output currents of SW 5V and ACC 5V. Therefore, the current supply capability of the VDD 5V output and its other electrical characteristics are affected by the output statuses of SW 5V and ACC 5V. 6. SW 5V and ACC 5V are not subject to a load. 7. When a component with a resistance accuracy of 1% is used When a component with a resistance accuracy of 0.5% is used, VO3” is 8.67V  9.0V  9.33V 8. When a component with a resistance accuracy of 1% is used The absolute accuracy of the internal resistance is 15% 9. Since the SW 5V and ACC 5V are output from VDD 5V through the SW, the voltage drops by an amount equivalent to the ON resistance of the SW. 10. The entire specification has been defined based on the tests performed under the conditions where Tj and Ta (=25C) are almost equal. There tests were performed with pulse load to minimize the increase of junction temperature (Tj). • Allowable power dissipation derating curve Pd max -- Ta Allowable power dissipation, Pd max -- W 8 Aluminum heat sink mounting conditions tightening torque : 39N⋅cm, using silicone grease 7 Aluminum heat sink (50 × 50 × 1.5mm3) when using 6 5.6 5 4 3 2 Independent IC 1.5 1 0 0 20 40 60 80 100 120 140 150 160 Ambient temperature, Ta -- °C • Waveform applied during surge test 50V 90% 10% 16V 5msec 100msec www.onsemi.com 4 LV5680NPVC Package Dimensions unit : mm HZIP15J CASE 945AC ISSUE A SOLDERING FOOTPRINT* Through Hole Area (Unit: mm) Package name HZIP15J 2.54 1.2 2.54 (1.91) 2.54 2.54 NOTE: The measurements are not to guarantee but for reference only. *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. www.onsemi.com 5 LV5680NPVC Block Diagram +B VCC + C1 7 C2 EXT out 15 ANT out Over Voltage Protection Start up + Vref CTRL1 8 (four-value control) CTRL2 6 (three-value control) + C3 D2 ANT Remote (VCC-0.5V) D3 300mA 14 + D4 C4 1 2 + Remote EXT (VCC-0.5V) D1 350mA 5 4 OUTPUT ILM output (8V to 12V) 300mA + R1 C6 C7 ILM_F AUDIO output (8V to 9V) 300mA + R2 C9 C10 AUDIO_F R3 Control + 3 + Thermal Shut Down CD output (8V) 1300mA + C11 C12 VDD output (5.0V) 200mA 12 + C13 C14 GND 9 13 ACC SW output (5V) 200mA 10 Output Current Limit Circuit www.onsemi.com 6 11 ACC output (5V) 100mA LV5680NPVC Pin Function Pin No. 1 Pin name ILM Description Equivalent Circuit ILM output pin VCC 7 ON when CTRL1 = M1, M2, H 12.0V/300mA 1 2 ILM_F 59.67kΩ ILM output voltage adjustment pin 2 7kΩ 3 CD CD output pin ON when CTRL2 = M, H 9 GND 7 VCC 8.0V/1.3A 3 214kΩ 40kΩ 4 AUDIO_F AUIDO output voltage adjustment pin 9 GND 7 VCC 5 5 AUDIO AUDIO output pin ON when CTRL2 = M, H 4 9 6 CTRL2 CTRL2 input pin three-value input GND VCC 7 6 7 VCC 500kΩ 9 GND Supply terminal Continued on next page. www.onsemi.com 7 LV5680NPVC Continued from preceding page. Pin No. 8 Pin name CTRL1 Description CTRL1 input pin four-value input Equivalent Circuit VCC 7 8 500kΩ 9 9 GND GND pin 10 ACC Accessory input GND VCC 7 10 45kΩ 15kΩ 9 11 ACC5V Accessory detection output ON when ACC  3V 12 VDD5V VDD5V output pin 5.0V/200mA GND VCC 7 12 371kΩ 11 13 SW5V SW5V output pin 13 ON when CTRL2 = M, H 50kΩ 50kΩ 9 14 ANT ANT output pin GND 7 ON when CTRL1 = H 125kΩ VCC VCC-0.5V/300mA 14 9 GND Continued on next page www.onsemi.com 8 LV5680NPVC Continued from preceding page. Pin No. 15 Pin name EXT Description Equivalent Circuit EXT output pin 7 ON when CTRL1 = M2, H VCC VCC-0.5V/350mA 15 9 www.onsemi.com 9 GND LV5680NPVC CTRL Pin Output Truth Table CTRL1 ANT EXT ILM CTRL2 CD AUDIO SW5 OFF L OFF OFF OFF L OFF OFF M1 OFF OFF ON M OFF ON ON M2 OFF ON ON H ON ON ON H ON ON ON Timing Chart 21V VCC (Pin 7) VDD5V output (Pin 12) CTRL1 input (Pin 8) CTRL2 input (Pin 6) CD output (Pin 3) AUDIO output (Pin 5) ILM output (Pin 1) EXT output (Pin 15) ANT output (Pin 14) SW5V output (Pin 13) ACC input (Pin 10) 3.0V 2.7V ACC output (Pin 11) www.onsemi.com 10 LV5680NPVC R1 R3 C9 + C10 ILM 12 11 CD EXT ANT SW5V VDD5V CTRL1 ACC 10 9 14 13 R2 15 + C4 CTRL2 C5 + C6 8 7 ACC5V 6 5 GND 4 3 VCC CTRL2 AUDIO 2 1 CD ILM ILM_F AUDIO_F Recommended Operation Circuit C7 + C8 AUDIO CTRL1 ACC ACC5V C1 + C2 SW5V C11 + C12 VCC VDD5V + C3 D3 D1 D4 D2 ANT EXT Peripheral parts list Name of part Description Recommended value Remarks C1 Power supply bypass capacitor 100F or more These capacitors must be placed near the C2 Oscillation prevention capacitor 0.22F or more VCC and GND pins. C3 EXT output stabilization capacitor 2.2F or more C4 ANT output stabilization capacitor 2.2F or more C5, C7, C9, C11 Output stabilization capacitor 4.7F or more Electrolytic capacitor * C6, C8, C10, C12 Output stabilization capacitor 0.22F or more Ceramic capacitor * R1 Resistor for ILM voltage adjustment ILM output voltage A resistor with resistance accuracy as low R1:without = 12.0V as less than 1% must be used. :270k = 10.0V :100k = 8.0V AUDIO output voltage R2, R3 R2/R3:30k/5.6k = 8.0V Resistor for AUDIO voltage setting :27k/4.7k = 8.5V A resistor with resistance accuracy as low as less than 1% must be used. :24k/3.9k = 9.0V D1, D2, D3, D4 Diode for internal device breakdown protection * : In order to stabilize the regulator outputs, it is recommended that the electrolytic capacitor and ceramic capacitor be connected in parallel. Furthermore, the values listed above do not guarantee stabilization during the overcurrent protection operations of the regulator, so oscillation may occur during an overcurrent protection operation. www.onsemi.com 11 LV5680NPVC • ILM output voltage setting method Formula for ILM voltage calculation Z1  R2 //R3  1 ILM R2 59.67kΩ ILM  R3 Z1=R2/R3 1.26V 2 ILM_F Z1  R2  R3 R2  R3 1.26[V ]  Z1  1.26[V ] R1 ILM  1.26  R1 1.26 R3  R2  Z 1 R2  Z 1 Example : ILM = 9V setting method R1 7kΩ Z1  The ILM_F voltage is determined by the internal band gap voltage of the IC (typ = 1.26V). R3  9V  1.26V   7kΩ  43kΩ 1.26V 59.67 k  43k  153.9k  150k 59.67k  43k When R3 = 150k, the ILM output voltage will be as follows: 59.67 kΩ 150kΩ Z1   42.69kΩ 59.67 kΩ  150kΩ ILM  1.26V  42.69kΩ  1.26V  8.94V 7 kΩ • AUDIO output voltage setting method Formula for AUDIO voltage calculation AUDIO  5 1.26[V ]  R1  1.26[V ] R2 R1  AUDIO  1.26   1.26 R2 AUDIO R1 1.26V 4 The circuit must be designed in such a way that the R1:R2 ratio satisfies the formula given above for the AUDIO voltage that has been set. AUDIO_F R2 Example : AUDIO = 8.5V setting method The AUDIO_F voltage is determined by the internal band gap voltage of the IC (typ = 1.26V). R1 8.5  1.26    5.75 R2 1.26 R1 27 kΩ   5.74 R2 4.7 kΩ AUDIO  1.26V  5.74  1.26V  8.49V Note : In the above, the typical values are given in all instances for the values used and, as such, they will vary due to the effects of production-related variations of the IC and external resistors. www.onsemi.com 12 LV5680NPVC • CTRL1 Application Circuit Example (1) 3.3V input: R1 = 4.7k, R2 = 10k A B R1 R2 CTRL1 500kΩ A B CTRL1 0V 0V 0V 0V 3.3V 1.05V 3.3V 0V 2.23V 3.3V 3.3V 3.20V • CTRL2 Application Circuit Example (1) 3.3V input: R3 = R4 = 4.7k C D R3 R4 CTRL2 500kΩ A B 0V 0V CTRL2 0V 0V 3.3V 1.61V 3.3V 0V 1.61V 3.3V 3.3V 3.29V www.onsemi.com 13 LV5680NPVC HZIP15J Heat sink attachment Heat sinks are used to lower the semiconductor device junction temperature by leading the head generated by the device to the outer environment and dissipating that heat. a.Unless otherwise specified, for power ICs with tabs and power ICs with attached heat sinks, solder must not be applied to the heat sink or tabs. b. Heat sink attachment · Use flat-head screws to attach heat sinks. · Use also washer to protect the package. · Use tightening torques in the ranges 39-59Ncm(4-6kgcm) . · If tapping screws are used, do not use screws with a diameter larger than the holes in the semiconductor device itself. · Do not make gap, dust, or other contaminants to get between the semiconductor device and the tab or heat sink. · Take care a position of via hole . · Do not allow dirt, dust, or other contaminants to get between the semiconductor device and the tab or heat sink. · Verify that there are no press burrs or screw-hole burrs on the heat sink. · Warping in heat sinks and printed circuit boards must be no more than 0.05 mm between screw holes, for either concave or convex warping. · Twisting must be limited to under 0.05 mm. · Heat sink and semiconductor device are mounted in parallel. Take care of electric or compressed air drivers · The speed of these torque wrenches should never exceed 700 rpm, and should typically be about 400 rpm. Binding head machine screw Countersunk head mashine screw Heat sink gap Via hole c.Silicone grease · Spread the silicone grease evenly when mounting heat sinks. · Our company recommends YG-6260 (Momentive Performance Materials Japan LLC) d. Mount · First mount the heat sink on the semiconductor device, and then mount that assembly on the printed circuit board. · When attaching a heat sink after mounting a semiconductor device into the printed circuit board, when tightening up a heat sink with the screw, the mechanical stress which is impossible to the semiconductor device and the pin doesn't hang. e.When mounting the semiconductor device to the heat sink using jigs, etc., · Take care not to allow the device to ride onto the jig or positioning dowel. · Design the jig so that no unreasonable mechanical stress is not applied to the semiconductor device. f. Heat sink screw holes · Be sure that chamfering and shear drop of heat sinks must not be larger than the diameter of screw head used. · When using nuts, do not make the heat sink hole diameters larger than the diameter of the head of the screws used. A hole diameter about 15% larger than the diameter of the screw is desirable. · When tap screws are used, be sure that the diameter of the holes in the heat sink are not too small. A diameter about 15% smaller than the diameter of the screw is desirable. g. There is a method to mount the semiconductor device to the heat sink by using a spring band. But this method is not recommended because of possible displacement due to fluctuation of the spring force with time or vibration. www.onsemi.com 14 LV5680NPVC Caution for implementing LV5680P to a system board The package of LV5680P is HZIP15J which has some metal exposures other than connection pins and heatsink as shown in the diagram below. The electrical potentials of (2) and (3) are the same as those of pin 15 and pin 1, respectively. (2) (=pin 15) is the VCC pin and (3) (=pin 1) is the ILM (regulator) output pin. When you implement the IC to the set board, make sure that the bolts and the heatsink are out of touch from (2) and (3). If the metal exposures touch the bolts which has the same electrical potential with GND, GND short occurs in ILM output and VCC. The exposures of (1) are connected to heatsink which has the same electrical potential with substrate of the IC chip (GND). Therefore, (1) and GND electrical potential of the set board can connect each other. • HZIP15J outline Heat-sink 1 Same potential 2 15PIN Same potential 1PIN 3 Same potential Heat-sink 1 Same potential Heat-sink side 1 Heat-sink Same potential :Metal exposure Heat-sink side :Metal exposure • Frame diagram (LV5680NPVC) *In the system power supply other than LV5680NPVC, pin assignment may differ. Metal exposure 1 Metal exposure 3 Metal exposure 2 LV5680NPVC Metal exposure 1 Metal exposure 1 Metal exposure 1 15PIN 1PIN www.onsemi.com 15 LV5680NPVC ON Semiconductor and the ON Semiconductor logo are trademarks of Semiconductor Components Industries, LLC dba ON Semiconductor or its subsidiaries in the United States and/or other countries. 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