specifications of any and all sanyo semiconductor co.,ltd. products described or contained herein stipulate the performance, characteristics, and functions of the described products in the independent state, and are not guarantees of the performance, characteristics, and functions of the described products as mounted in the customer ' s products or equipment. to verify symptoms and states that cannot be evaluated in an independent device, the customer should always evaluate and test devices mounted in the customer ' s products or equipment. any and all sanyo semiconductor co.,ltd. products described or contained herein are, with regard to "standard application", intended for the use as general electronics equipment. the products mentioned herein shall not be intended for use for any "special application" (medical equipment whose purpose is to sustain life, aerospace instrument, nuclear control device, burning appliances, transportation machine, traffic signal system, safety equipment etc.) that shall require extremely high level of reliability and can directly threaten human lives in case of failure or malfunction of the product or may cause harm to human bodies, nor shall they grant any guarantee thereof. if you should intend to use our products for new introduction or other application different from current conditions on the usage of automotive device, communication device, office equipment, industrial equipment etc. , please consult with us about usage conditi on (temperature, operation time etc.) prior to the intended use. if there is no consultation or inquiry before the intended use, our customer shall be solely responsible for the use. 20812 sy 20120118-s00002 no.a2003-1/9 LV5065VB overview the LV5065VB is a high efficiency dc /dc converter controller with 2-channels ic adopting a synchronous rectifying system. incorporating numerous functions on a single chip with easy external setting, it can be used for a wide variety of applications. this device is optimal for use in internal power supply systems which ar e used in electronic devices, lcd-tvs, dvd recorders, etc. functions ? step-down dc/dc converter controller with 2-channel ? built-in input uvlo circuit, over current detection functio n, soft-start/soft-stop function and start-up delay circuit ? built-in output voltage monitor function (under vo ltage protection with power good and timer latch) ? 180 degree interleaving operation during 1-phase to 2-phase ? synchronized operation is possible (master-slave operation is possible when using plural devices) specifications absolute maximum ratings at ta = 25 c parameter symbol conditions ratings unit maximum supply voltage v cc max 20 v output peak current i out 1.0 a allowable power dissipation pd max mounted on a specified board * 0.95 w operating temperature topr -20 to 85 c storage temperature tstg -55 to +150 c *: specified board: 114.3mm 76.1mm 1.6mm, glass epoxy board . caution 1) absolute maximum ratings represent the va lue which cannot be exceeded for any length of time. caution 2) even when the device is used within the range of absolu te maximum ratings, as a result of continuous usage under hig h temperature, high current, high voltage, or drastic temperature change, the reliability of the ic may be degraded. please contact us for the further details. continued on next page. bi-cmos ic built-in 2-channels dc/dc converter controller orderin g numbe r : ena2003
LV5065VB no.a2003-2/9 continued from preceding page. parameter symbol conditions ratings unit allowable terminal voltage 1 between hdrv1,2, cboot1,2 and pgnd 25 v 2 between hdrv1,2, cboot1,2 and sw 6.5 v 3 v in , ilim1,2, rsns1,2, sw1,2, pgood1,2 20 v 4 vlin5, v dd , ldrv1,2 6.5 v 5 comp1,2, fb1,2, ss1,2, uv_delay,td1,2, ct, clko vlin5+0.3 v recommended operating condition at ta = 25 c parameter symbol conditions ratings unit recommended supply voltage range v in 9.5 to 18 v electrical characteristics at ta = 25 c, v in =12v, unless especially specified. parameter symbol conditions ratings unit min typ max system reference voltage for comparing v ref v in = 15 1% 0.633 +1% v supply current 1 i cc 1 td1,2 = 5v, v in = 15 (except for the ciss charge) 4 6 8 ma supply current 2 i cc 2 td1,2 = 0v, v in = 15 0.8 1.4 2.0 ma 5v supply voltage vlin5 v in = 15, ivin5 = 0 to 10ma 5.10 5.30 5.50 v over-current sense comparator offset v cl os -5 +5 mv over-current sense reference current source i cl v in = 12 to 15v *1 60.45 65.00 69.55 a soft start source current i ss sc td = 5v -1.8 -3.5 -7.0 a soft start sink current i ss sk td = 0v 0.2 1.0 ma soft start clamp voltage v ss t0 1.2 1.6 2.0 v uv_delay source current i sc uvd uv_delay = 2v -4.3 -8.6 -17.2 a uv_delay sink current i sk uvd uv_delay = 2v 0.2 1.0 ma uv_delay threshold voltage v uvd 1.5 2.4 3.5 v uv_delay operating voltage v uvp 100% at vfbx = v ref 77 82 87 % vuvp detection hysteresis v uvp 8 % over-voltage detection v o vp 100% at vfbx = v ref 113 118 123 % output discharge transistor on resistance v sw on 5 10 20 output part cboot leakage current i cboot vcboot = vsw + 6.5v 10 a hdrvx ldrvx source current i sc drv 1.0 a hdrvx ldrvx sink current i sk drv 1.0 a hdrvx lower on resistance r h drv i out = 500ma 1.5 2.5 ldrvx lower on resistance r l drv i out = 500ma 1.5 2.5 synchronous on prevention dead time 1 t dead 1 ldrv off hdrv on 50 ns synchronous on prevention dead time 2 t dead 2 hdrv off ldrv on 50 ns ldrv_on delay time mdead hdrv off ldrv on at max_duty 50 ns oscillator oscillation frequency f osc v in = 15, ct=270pf 170 200 230 khz oscillation frequency range f osc op v in = 15 100 500 khz maximum on duty d on max v in = 15, ct=270pf 90 95 % minimum on time t on min v in = 15, ct=270pf 120 ns upper-side voltage saw- tooth wave v saw h f osc =200khz, rsns=v in (0 ) 2.75 3.2 v lower-side voltage saw-tooth wave v saw l f osc =200khz 1 1.2 v on time difference between ch1 to ch2 tdead 5 % continued on next page.
LV5065VB no.a2003-3/9 continued from preceding page. parameter symbol conditions ratings unit min typ max error amplifier error amplifier input current i fb -200 -100 200 na comp pin source current i comp sc -100 -18 a comp pin sink current i comp sk 18 100 a error amplifier gm gm 500 700 900 umho current detection amplifier gain gisns 3 4 5 logic output power good low level source current i pwrgd l v pgood = 0.4v 0.5 1.0 ma power good high level leakage current i pwrgd h v pgood = 15v 10 a tp pin threshold voltage v on td when the voltage of the td pin rises 1.5 2.6 3.5 v tp pin high impedance voltage v td h when v in and vlin5 pins are set to open 4.5 5.2 5.5 v td pin charge source current i td sc -1.8 -3.5 -7.0 a td pin discharge sink current i td sk 0.2 1.0 ma clko high level voltage v clko h i clko = 1ma 0.7v5lin v clko low level voltage v clko l i clko = 1ma 0.3v5lin v protection function v in uvlo release voltage v uvlo 3.5 4.1 4.3 ma uvlo hysteresis v uvlo 0.4 a *1: the overcurrent detection standard current so urce assumes it a measurement standard package dimensions unit : mm (typ) 3421 pin assignment 0 pd max - ta -20 1200 600 200 800 400 20 04060 80 100 494 85 1000 950 ambient temperature, ta -- c allowable power dissipation, pd max -- mw specified board: 114.3 76.1 1.6mm 3 glass epoxy board. sanyo : ssop30(225mil) 8.0 4.4 0.1 6.4 12 30 0.15 0.5 0.22 0.5 (0.5) 1.7 max (1.5) 30 29 28 27 26 25 24 23 22 21 1 sw1 2 hdrv1 3 cboot1 4 vlin5 5 rsns1 6 7 ilim1 8 td1 20 19 14 13 12 11 9 10 pgnd ldrv1 uv_delay ct clko ss1 v in 18 17 16 15 v dd sgnd fb1 LV5065VB top view comp1 pgood1 hdrv2 ldrv2 sw2 cboot2 comp2 fb2 rsns2 ilim2 td2 ss2 pgood2
LV5065VB no.a2003-4/9 block diagram vin 5v reg (always on) internal bias vlin5 5.3v vin ilim comp sense amp ilim1 rsns1 cboot1 hdrv1 r s q q shifter & latch sw1 shoot through protection sequencer v dd ldrv1 pwm logic skip control sd por pwm comp corrective ramp 0 deg ss1en d vref 1.6v sd por 2.6v cont1 uv1 ov1 0.82vref 1.17vref comp1 fb1 ch1 output ss1 td1 vin ilim comp sense amp ilim2 rsns2 cboot2 hdrv2 r s q q shifter & latch sw2 shoot through protection sequencer ldrv2 pwm logic skip control sd pwm comp corrective ramp 180 deg ss2en d vref 1.6v sd por 2.6v cont2 uv2 ov2 0.82vref 1.17vref comp2 fb2 ch2 output ss2 td2 ch1 output ch2 output pgnd r s q q 0v uv timeout 2.6v cont1 cont2 por ov1 ov2 ss1en d ss2en d uv1 uv2 pgood1 pgood2 uv_delay 0 deg 180 deg osc 200khz ct clko sync. pulse out 0v 5v sgnd vlin5 vin voltage and current generator current bias bg reference bg iref input power supply vref 0.63v error amp error amp 9.0v /8.0v 4.0v /3.5v vref
LV5065VB no.a2003-5/9 pin functions pin no. pin name description 1 v dd power supply pin for the gate drive of an external lower-side mos-fet. this pin is connected to the vlin5 pin through a filter. 2 ldrv the gate drive pin of an external lower-side mos-fet of channel 1. this pin has the signal input part for prevention of short-through of both the upper and lower mos-fets. when the voltage of this pin becomes less than 2v, the hdrv pin is turned on. 3 hdrv1 the gate drive pin for an external upper side mos-fet of channel 1. 4 sw1 this pin is connected with the switching node of channel 1. a source of an external upper side mosfet and a drain of an external lower side mos-fet are connected with this pin. this pin become s the return current pa th of the hdrv pin. this pin is connected with a transistor drain of the discharge mos-fet for soft stop in the ic (typical 30 ). also, this pin has the signal output part for the short through prevention of both the upper and lower mos-fets. when this terminal voltage becomes 2v or less for pgnd, the ldrv pin is turned on. 5 cboot1 the bootstrap capacity connection pin of channel 1. the gate drive power of upper mosf et is provided by this pin. this pin is connected to the v dd pin through a diode and is connected to the sw pin through the bootstrap capacity. 6 vlin5 the output pin of an in ternal regulator of 5v. the current is provided by the v in pin. also, power supply of the control circuit in the ic is provided by this pin. connect an output capacitor of 1 f between this pin and sgnd. a regulator of 5v operates, even if the ic is in the standby state. this pin is monitored by an uvlo function and the ic starts by the voltage of 4.0v or more (t he ic is off by the voltage of 3.5v or less.) 7 comp1 the phase compensation pin of channel 1. the output of an internal transforme r conductance amplifier is connected. connect an external phase compensation circuit between this pin and sgnd. 8 fb1 feed back input pin of channel 1. the minus terminal (-) of the trans conductance amplifier is connected. the voltage generated when the output voltage was divided by a resistor is input into this pin. the converter operates so that this pin becomes an internal reference voltage (v ref =0.63v). also, this pin is monitored by the comparators uvp and ovp. when the voltage of this pin becomes less than 82% of the set voltage, the pgood pin is low level. a timer of the uv_delay function operates. also, when the volt age of this pin becomes more than 118% of the set voltage, the ic latches off. 9 rsns1 channel 1 side input pin of the over current dete ction comparator / the curr ent detection amplifier. to detect resistance, this pin is connected to the under si de of a resistor for the current detection between the v in pin and the drain of the upper mos-fet. also, to use the on resistance of mos-fet for the current de tection, connect this pin to the source of the upper mos-fet. to prevent the common impedance of main current to the detection-voltage, this pin is connected by independent wiring. 10 ilim the pin to set the trip point fo r over current detection of channel 1. since the sink current source of 65 a (ilim) is connected in the ic, the over-current detection voltage (ilim rlim) is generated by connecting a resistor rlim between this pin and the v in pin. the over-current is detected by comparing the voltage between the v in pin and the ilim pin to the current detection resistance rsns or both end voltage of the upper mosfet. 11 td start-up delay pin of channel 1. the time until the ic starts after releasing por is set by connecting a capacitor between this pin and sgnd. after releasing por, an external capacitor is ch arged up by the constant current source of 3.5 a in the ic. when this terminal voltage becom es 2.6v or more, the ic starts. also, when th is terminal voltage becomes 2.6v or less, the ic becomes the standby state. if external capacitor is not connected, the ic instant ly starts after releasing por. 12 ss1 the pin to connect a capacit or for soft start of channel 1. after releasing por, when the voltage of the td pin becomes 2. 6v or more, the ss1 pin is charged by an internal constant current source of 3.5 a. since this pin is connected to the positive (+) input of the transformer c onductance amplifier, the ramp-up wave form of the ss pin become s the ramp-up wave form of the output. during por operations and after the uv_delay time-out, the ss1 pin is discharged 13 pgood the power good pin of channel 1. the open drain mos- fet of the withstand of 18v is connected in the ic. when the output voltage of channel 1 is less than -13% for the setup voltage, the low level is output. this pin has hysteresis of about (v ref 8.0%). 14 uv_delay common uvp delay pin to channel 1 and channel 2. by connecting a capacitor between this pin and sgnd, the time un til the ic latches off after detecting the uvp state can be set. also, after channel 1 or channel 2 te rminated the soft-start function, when th e output voltage becomes 82% or less for the setup voltage, an external capacitor is c harged by the constant current source of 8.6 a in the ic. when this terminal voltage becomes 2.6v or more, the ic is latched off. if an external capacitor is not c onnected, the ic is instantly latched off after detecting the uvp state. also, when this pin is shorted to gnd, the uv_delay function is not operated. continued on next page.
LV5065VB no.a2003-6/9 continued from preceding page. pin no. pin name description 15 v in power supply pin of the ic. this pin is observed by the uvlo function and ic starts by 9.0v or more. (after starts, stop by 8.0v or less. ) 16 clko the clock output pin. the clock that synchronized to the oscillation waveform of the ct pin is output. to synchronize two or more lv5052vs, the clko pin of the devic e that becomes a master is connected to the ct pin of the device that becomes a slave. when two or more the devices are synchronized and the start-up timing is changed by using the td pin between each device, the earliest st art-up device is determined as the master. 17 ct the pin to connect an external capacitor for the osci llator. connect a capacitor between this pin and sgnd. when a capacitor of 270pf is connected between this pin and gnd, the oscillation frequency can be set up by 200khz. also, this pin is applied by an external clock signal. the pwm operation is performed by t he frequency of applied clock signal. when an external clock signal is applied, the rectangular wave of 0v in low level and from 0v / 3.3v to 5v in high level is applied. the rectangular wave source needs the fan-out of 1ma or more. 18 pgood2 the power good pin of channel 2. 19 ss2 the pin to connect a capacit or for soft start of channel 2. 20 td2 start-up delay pin of channel 2. 21 ilim2 the pin to set the trip point fo r over current detection of channel 2. 22 rsns2 channel 2 side input pin of the over current dete ction comparator / the curr ent detection amplifier. 23 fb2 feed back input pin of channel 2. 24 comp2 the phase compensation pin of channel 2. 25 sgnd the system ground of the ic. the refer ence voltage is generated based on this pin. this pin is connected to the power supply system ground. 26 cboot2 the bootstrap capacity connection pin of channel 2. 27 sw2 this pin is connected with the switching node of channel 2. 28 hdrv2 the gate drive pin for an external upper side mos-fet of channel 2. 29 ldrv2 the gate drive pin of an external lower-side mos-fet of channel 2. 30 pgnd power ground pin. this pin becomes the return current path of the ldrv pin.
LV5065VB no.a2003-7/9 start-up sequence each signal control timing at power supply on is as below. v in vlin5 td ss vout pgood 9v typ 4.0v typ 2.6v typ 0.63v vout 82% v in =15v vlin5=5v td=5v ss=1.6v vout=vout 100% uvlo release * * starts charging the td at the trigger point of either vin > 9v(typ) or vlin5 > 4.5v(typ), whichever is later. protection operate sequence (1) latch-off release by uvlo the signal control timing diagram for resetting the latch-off condition using uvlo is shown below. v in vlin5 td ss vout pgood v in =15v vlin5=5v td=5v ss=1.6v vout=vout 100% 8v typ 9v typ 2.6v typ 0.63v vout 82% vout 118% vout 82% ovp restart td discharge start (2) latch off release by td the signal control timing diagram for resetting the latch-off condition using uvlo is shown below. v in vlin5 td ss vout pgood v in =15v vlin5=5v td=5v ss=1.6v vout=vout 100% 2.6v typ 0.63v vout 82% vout 118% vout 82% ovp td discharge start
LV5065VB ps no.a2003-8/9 shoot through protection at the same time on prevention dead time1 (tdead1): ldrv off hdrv on ? hdrv is turned on after typ_50ns after ldrv became 2v in the ldrv off hdrv on. at the same time on prevention dead time2 (tdead2): hdrv off ldrv on ? ldrv is turned on after typ_50ns after sw became 2v in the hdrv off ldrv on. ldrv compulsion on delay time ? even if sw does not reac h 2v when hdrv reaches max _duty, ldrv is performed on of forcibly after about 50ns. this price changes by ciss of the external mosfet. ldrv hdrv sw at the same time on prevention dead time 1 typ_50ns ldrv hdrv sw vth_2v at the same time on prevention dead time 2 typ_50ns ldrv hdrv sw hdrv-sw (hi-side_mosfet_vgs) ldrv compulsion on timing max_duty time dead time typ_50ns
LV5065VB ps no.a2003-9/9 synchronized operation a recommended circuit for synchronizing the lv5056vb is shown below. clko vin ct 270pf vin ct vin ct master slave vin (typ 15v) this catalog provides information as of february, 2 012. specifications and information herein are subject to change without notice. sanyo semiconductor co.,ltd. assumes no responsib ility for equipment failures that result from using products at values that exceed, even momentarily, rated values (such as maximum ratings, operating condition ranges, or other parameters) listed in products specifications of any and all sanyo semiconductor co.,ltd. products described or contained herein. sanyo semiconductor co.,ltd. strives to supply high-quality high-reliab ility pr oducts, however, any and all semiconductor products fail or malfunction with some probab ility. it is possible that these pr obab ilistic failures or malfunction could give rise to accidents or events that could endanger human lives, trouble that could give rise to smoke or fire, or accidents that could cause dam age to other property. when designing equipment, adopt safety measures so that these kinds of accidents or events cannot occur. such measures include but are not limited to protective circuits and error prevention circuits for safe design, redundant design, and structural design. upon using the technical information or products described herein, neither warranty nor license shall be granted with regard to intellectual property rights or any other rights of sanyo semiconductor co.,ltd. or any third party. sanyo semiconductor co.,ltd. shall not be liable for any claim or suits with regard to a third party's intellctual property rights which has resulted from the use of the technical information and products mentioned above. any and all information described or contained herein are subject to change without notice due to product/technology improvement, etc. when designing equip ment, refer to the "delivery specification" for the sanyo semiconductor co.,ltd. product that you intend to use. in the event that any or all sanyo semiconductor co.,ltd. products described or contained herein are controlled under any of applicable local export control laws and regulations, such products may require the export license from the authorities concerned in accordance with the above law. no part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, or any information storage or retrieval system, or otherwise, without the prior written consent of sanyo semiconductor co.,ltd.
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