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  ? 2007-2015 exar corporation 1 / 19 exar.com/clc1005 rev 2d features 260mhz bandwidth fully specifed at +2.7v and +5v supplies output voltage range: ? 0.036v to 4.953v; v s = +5; r l = 2k input voltage range: ? -0.3v to +3.8v; v s = +5 145v/s slew rate 4.2ma supply current power down to 127a 55ma linear output current 85ma short circuit current clc2005 directly replaces ad8052/42/92 in single supply applications clc1005 directly replaces ad8051/41/91 in single supply applications applications a/d driver active flters ccd imaging systems cd/dvd rom coaxial cable drivers high capacitive load driver portable/battery-powered applications twisted pair driver telecom and optical terminals video driver interactive whiteboards general description the clc1005 (single), clc1015 (single with disable), and clc2005 (dual) are low cost, voltage feedback amplifers. these amplifers are designed to operate on +2.7v to +5v, or 2.5v supplies. the input voltage range extends 300mv below the negative rail and 1.2v below the positive rail. the clc1005, clc1015, and clc2005 offer superior dynamic performance with 260mhz small signal bandwidth and 145v/s slew rate. the amplifers consume only 4.2ma of supply current per channel and the clc1015 offers a disable supply current of only 127a. the combination of low power, high output current drive, and rail-to-rail performance make these amplifers well suited for battery-powered communication/computing systems. the combination of low cost and high performance make the clc1005, clc1015, and clc2005 suitable for high volume applications in both consumer and industrial applications such as interactive whiteboards, wireless phones, scanners, color copiers, and video transmission. output swing output voltage (0.5v/div) time (0.5 s/div) 2.7 0 v s = +2.7v r l = 2k g = -1 2nd & 3rd harmonic distortion; v s = +2.7v distortion (dbc) frequency (mhz) 0 5 10 15 2nd r l = 150 20 3rd r l = 150 3rd r l = 2k 2nd r l = 2k -90 -80 -70 -60 -50 -40 -30 -20 v o = 1v pp r f = 1k ordering information - backpage clc1005, clc1015, clc2005 low cost, +2.7v to 5.5v, 260mhz rail-to-rail amplifiers
? 2007-2015 exar corporation 2 / 19 exar.com/clc1005 rev 2d absolute maximum ratings stresses beyond the limits listed below may cause permanent damage to the device. exposure to any absolute maximum rating condition for extended periods may affect device reliability and lifetime. v s ................................................................................... 0v to +6v v in ............................................................ -v s - 0.5v to +v s +0.5v operating conditions supply voltage range ................................................... 2.5 to 5.5v operating temperature range ................................. -40c to 85c junction temperature ........................................................... 150c storage temperature range ................................... -65c to 150c lead temperature (soldering, 10s) ...................................... 260c package thermal resistance ja (soic-8) ..................................................................... 150c/w ja (msop-8) .................................................................. 200c/w ja (tsot23-5) ................................................................ 215c/w ja (tsot23-6) ................................................................ 192c/w package thermal resistance ( ja ), jedec standard, multi-layer test boards, still air. esd protection soic-8 (hbm) ....................................................................... 2.5kv esd rating for hbm (human body model) and cdm (charged device model). clc1005, clc1015, clc2005
? 2007-2015 exar corporation 3 / 19 exar.com/clc1005 rev 2d electrical characteristics at +2.7v t a = 25c, v s = +2.7v, r f = 2k, r l = 2k to v s /2; g = 2; unless otherwise noted. symbol parameter conditions min ty p max units frequency domain response gbwp -3db gain bandwidth product 86 mhz ugbw unity gain bandwidth (1) g = +1, v out = 0.05v pp 215 mhz bw ss -3db bandwidth g = +2, v out = 0.2v pp 85 mhz bw ls large signal bandwidth g = +2, v out = 2v pp 36 mhz time domain t r , t f rise and fall time (1) v out = 0.2v step; (10% to 90%) 3.7 ns t s settling time to 0.1% v out = 1v step 40 ns os overshoot v out = 0.2v step 9 % sr slew rate g = -1, 2.7v step 130 v/s distortion/noise response hd2 2nd harmonic distortion (1) 5mhz, v out = 1v pp 79 dbc hd3 3rd harmonic distortion (1) 5mhz, v out = 1v pp 82 dbc thd total harmonic distortion (1) 5mhz, v out = 1v pp 77 db e n input voltage noise >1mhz 16 nv/hz i n input current noise >1mhz 1. 3 pa/hz x talk crosstalk (1) clc2005, 10mhz 65 db dc performance v io input offset voltage -1.6 mv d vio average drift 10 v/c i b input bias current 3 a di b average drift 7 na/c i os input offset current 0.1 a psrr power supply rejection ratio dc 52 57 db a ol open loop gain 75 db i s supply current 3.9 ma disable characteristics (clc1015) t on turn on time 150 ns t off turn off time 25 ns off iso off isolation 5mhz, r l = 100 75 db i sd disable supply current dis tied to gnd 58 100 a input characteristics r in input resistance 4.3 m c in input capacitance 1. 8 pf cmir common mode input range -0.3 to 1.5 v cmrr common mode rejection ratio dc, v cm = 0 to v s - 1.5v 87 db output characteristics v out output swing r l = 10k to v s / 2 0.023 to 2.66 v r l = 2k to v s / 2 0.025 to 2.653 v r l = 150 to v s / 2 0.065 to 2.55 v i out output current 55 ma -40c to +85c 50 ma i sc short circuit current v out = v s / 2 85 ma v s power supply operating range 2.5 2.7 5.5 v notes: 1. r f = 1k was used for optimal performance. (for g = +1, r f = 0) clc1005, clc1015, clc2005
? 2007-2015 exar corporation 4 / 19 exar.com/clc1005 rev 2d electrical characteristics at +5v t a = 25c, v s = +5v, r f = 2k, r l = 2k to v s /2; g = 2; unless otherwise noted. symbol parameter conditions min ty p max units frequency domain response gbwp -3db gain bandwidth product 90 mhz ugbw unity gain bandwidth (1) g = +1, v out = 0.05v pp 260 mhz bw ss -3db bandwidth g = +2, v out = 0.2v pp 90 mhz bw ls large signal bandwidth g = +2, v out = 2v pp 40 mhz time domain t r , t f rise and fall time (1) v out = 0.2v step 3.6 ns t s settling time to 0.1% v out = 2v step 40 ns os overshoot v out = 0.2v step 7 % sr slew rate g = -1, 5v step 145 v/s distortion/noise response hd2 2nd harmonic distortion (1) 5mhz, v out = 2v pp 71 dbc hd3 3rd harmonic distortion (1) 5mhz, v out = 2v pp 78 dbc thd total harmonic distortion (1) 5mhz, v out = 2v pp 70 db dg differential gain ntsc (3.85mhz), ac-coupled, r l = 150 0.06 % ntsc (3.85mhz), dc-coupled, r l = 150 0.08 % dp differential phase ntsc (3.85mhz), ac-coupled, r l = 150 0.07 ntsc (3.85mhz), dc-coupled, r l = 150 0.06 e n input voltage noise >1mhz 16 nv/hz i n input current noise >1mhz 1. 3 pa/hz x talk crosstalk (1) clc2005, 10mhz 62 db dc performance v io input offset voltage -8 1. 4 8 mv d vio average drift 10 v/c i b input bias current -8 3 8 a di b average drift 7 na/c i os input offset current -0.8 0.1 0.8 a psrr power supply rejection ratio dc 52 57 db a ol open loop gain 68 78 db i s supply current 4.2 5.2 ma disable characteristics (clc1015) t on turn on time 150 ns t off turn off time 25 ns off iso off isolation 5mhz, r l = 100 75 db i sd disable supply current dis tied to gnd 127 170 a input characteristics r in input resistance 4.3 m c in input capacitance 1. 8 pf cmir common mode input range -0.3 to 3.8 v cmrr common mode rejection ratio dc, v cm = 0 to v s - 1.5v 72 87 db clc1005, clc1015, clc2005
? 2007-2015 exar corporation 5 / 19 exar.com/clc1005 rev 2d electrical characteristics at +5v continued t a = 25c, v s = +5v, r f = 2k, r l = 2k to v s /2; g = 2; unless otherwise noted. symbol parameter conditions min ty p max units output characteristics v out output swing r l = 10k to v s / 2 0.027 to 4.97 v r l = 2k to v s / 2 0.036 to 4.953 v r l = 150 to v s / 2 0.3 0.12 to 4.8 4.625 v i out output current 55 ma -40c to +85c 50 ma i sc short circuit current v out = v s / 2 85 ma v s power supply operating range 2.5 5 5.5 v notes: 1. r f = 1k was used for optimal performance. (for g = +1, r f = 0) clc1005, clc1015, clc2005
? 2007-2015 exar corporation 6 / 19 exar.com/clc1005 rev 2d clc1015 pin assignments tsot-6 pin no. pin name description 1 out output 2 -v s negative supply 3 +in positive input 4 -in negative input 5 dis disable pin. enabled if pin is left open or tied to +v s , disabled if pin is tied to -v s (which is gnd in a single supply application.) 6 +v s positive supply clc1015 pin confgurations tsot-6 - + 2 3 6 4 +in + v s 5 dis -in 1 - v s out soic-8 pin no. pin name description 1 nc no connect 2 -in negative input 3 +in positive input 4 -v s negative supply 5 nc no connect 6 out output 7 +v s positive supply 8 nc no connect soic-8 - + 1 2 3 4 nc -in +in -v s nc +v s out nc 8 7 6 5 clc1005 pin assignments tsot-5 pin no. pin name description 1 out output 2 -v s negative supply 3 +in positive input 4 -in negative input 5 +v s positive supply clc1005 pin confgurations tsot-5 - + 2 3 5 4 +in + v s -in 1 - v s out clc1005, clc1015, clc2005
? 2007-2015 exar corporation 7 / 19 exar.com/clc1005 rev 2d clc2005 pin assignments soic-8 / msop-8 pin no. pin name description 1 out1 output, channel 1 2 -in1 negative input, channel 1 3 +in1 positive input, channel 1 4 -v s negative supply 5 +in2 positive input, channel 2 6 -in2 negative input, channel 2 7 out2 output, channel 2 8 +v s positive supply clc2005 pin confguration soic-8 / msop-8 - + - + 1 2 3 4 out1 -in1 +in1 -v s +v s out2 -in2 +in2 8 7 6 5 clc1005, clc1015, clc2005
? 2007-2015 exar corporation 8 / 19 exar.com/clc1005 rev 2d typical performance characteristics t a = 25c, v s = +5v, r l = 2k to v s /2, g = +2, r f = 2k; unless otherwise noted. frequency response vs c l large signal frequency response non-inverting frequency response v s = +2.7v inverting frequency response v s = +2.7v non-inverting frequency response v s = +5v inverting frequency response v s = +5v normalized magnitude (2db/div) frequency (mhz) 0.1 1 g = 10 r f = 2k 10 100 g = 5 r f = 2k g = 1 r f = 0 g = 2 r f = 1k normalized magnitude (1db/div) frequency (mhz) 0.1 1 g = -10 r f = 2k 10 100 g = -5 r f = 2k g = -2 r f = 2k g = -1 r f = 2k normalized magnitude (2db/div) frequency (mhz) 1 10 100 0.1 g = 10 r f = 2k g = 5 r f = 2k g = 1 r f = 0 g = 2 r f = 1k normalized magnitude (1db/div) frequency (mhz) 0.1 1 g = -10 r f = 2k 10 100 g = -5 r f = 2k g = -2 r f = 2k g = -1 r f = 2k magnitude (1db/div) frequency (mhz) 0.1 1 10 100 c l = 100pf r s = 25 c l = 50pf r s = 33 c l = 20pf r s = 20 c l = 10pf r s = 0 + - 1kw 1kw r s c l r l magnitude (1db/div) frequency (mhz) 0.1 1 10 100 v o = 1v pp v o = 2v pp clc1005, clc1015, clc2005
? 2007-2015 exar corporation 9 / 19 exar.com/clc1005 rev 2d typical performance characteristics t a = 25c, v s = +5v, r l = 2k to v s /2, g = +2, r f = 2k; unless otherwise noted. 2nd harmonic distortion vs v o 3rd harmonic distortion vs v o 2nd & 3rd harmonic distortion v s = +5v 2nd & 3rd harmonic distortion v s = +2.7v frequency response vs. temperature input voltage noise vs frequency magnitude (0.5db/div) frequency (mhz) 1 10 100 voltage noise (nv/hz) frequency (hz) 1k 10k 100k 1m 0 10 20 30 40 50 60 70 80 90 100 distortion (dbc) frequency (mhz) 0 5 10 15 3rd r l = 150 20 2nd r l = 150 3rd r l = 2k 2nd r l = 2k -90 -80 -70 -60 -50 -40 -30 -20 v o = 2v pp r f = 1k distortion (dbc) frequency (mhz) 0 5 10 15 2nd r l = 150 20 3rd r l = 150 3rd r l = 2k 2nd r l = 2k -90 -80 -70 -60 -50 -40 -30 -20 v o = 1v pp r f = 1k distortion (dbc) output amplitude (v pp ) 0.5 1. 0 1. 5 2.0 20mhz 10mhz 5mhz 2.5 -90 -80 -70 -60 -50 -40 -30 -20 r f = 1k 2mhz distortion (dbc) output amplitude (v pp ) 0.5 1. 0 1. 5 2.0 20mhz 10mhz 5mhz 2.5 -90 -80 -70 -60 -50 -40 -30 -20 r f = 1k 2mhz clc1005, clc1015, clc2005
? 2007-2015 exar corporation 10 / 19 exar.com/clc1005 rev 2d typical performance characteristics t a = 25c, v s = +5v, r l = 2k to v s /2, g = +2, r f = 2k; unless otherwise noted. small signal pulse response v s = +5v small signal pulse response v s = +2.7v open loop gain & phase vs. frequency output current psrr cmrr psrr (db) frequency (mhz) 1k 0.01 0.1 1 100 -70 -60 -50 -40 -30 -20 -10 0 10 cmrr (db) frequency (mhz) 0.01 0.1 1. 0 10 100 -90 -80 -70 -60 -50 -40 open loop gain (db) frequency (mhz) -20 -10 0 10 20 -180 -135 -90 -45 0 30 40 50 60 70 80 0.01 0.1 1 10 100 phase (degrees) |gain| phase output voltage (v) output current (ma) -100 -50 0 50 100 linear output current 55ma -0.8 -0.6 -0.2 0 0.2 0.4 0.6 0.8 -0.4 short circuit current 85ma output voltage (0.05v/div) time (20ns/div) r f = 1k output voltage (0.05v/div) time (20ns/div) r f = 1k clc1005, clc1015, clc2005
? 2007-2015 exar corporation 11 / 19 exar.com/clc1005 rev 2d typical performance characteristics t a = 25c, v s = +5v, r l = 2k to v s /2, g = +2, r f = 2k; unless otherwise noted. channel matching v s = +5v large signal pulse response v s = +5v output swing output voltage (0.5v/div) time (20ns/div) r f = 1k output voltage (0.5v/div) time (0.5 s/div) 2.7 0 v s = +2.7v r l = 2k g = -1 magnitude (0.5db/div) frequency (mhz) 0.1 1 10 100 channel 1 r f = 1k r l = 2k g = 2 channel 2 clc1005, clc1015, clc2005
? 2007-2015 exar corporation 12 / 19 exar.com/clc1005 rev 2d application information general description the clc1005, clc1015, and clc2005 are single supply, general purpose, voltage-feedback amplifers fabricated on a complementary bipolar process using a patented topography. they feature a rail-to-rail output stage and are unity gain stable. both gain bandwidth and slew rate are insensitive to temperature. the common mode input range extends to 300mv below ground and to 1.2v below v s . exceeding these values will not cause phase reversal. however, if the input voltage exceeds the rails by more than 0.5v, the input esd devices will begin to conduct. the output will stay at the rail during this overdrive condition. the design is short circuit protected and offers soft saturation protection that improves recovery time. figures 1, 2, and 3 illustrate typical circuit confgurations for non-inverting, inverting, and unity gain topologies for dual supply applications. they show the recommended bypass capacitor values and overall closed loop gain equations. figure 4 shows the typical non-inverting gain circuit for single supply applications. + - r f 0.1f 6.8f output g = 1 + (r f /r g ) input +v s -v s r g 0.1f 6.8f r l figure 1: typical non-inverting gain circuit + - r f 0.1f 6.8f output g = - (r f /r g ) for optimum input offset voltage set r 1 = r f || r g input +v s -v s 0.1f 6.8f r l r g r 1 figure 2: typical inverting gain circuit + - 0.1f 6.8f output g = 1 input +v s -v s 0.1f 6.8f r l figure 3: unity gain circuit + - r f 0.1f 6.8f out in +v s + r g figure 4: single supply non-inverting gain circuit at non-inverting gains other than g = +1, keep r g below 1k to minimize peaking; thus for optimum response at a gain of +2, a feedback resistor of 1k is recommended. figure 5 illustrates the clc1005, clc1015 and clc2005 frequency response with both 1k and 2k feedback resistors. magnitude (1db/div) frequency (mhz) 1 10 100 r f = 2k r f = 1k g = 2 r l = 2k v s = +5v figure 5: frequency response vs. r f clc1005, clc1015, clc2005
? 2007-2015 exar corporation 13 / 19 exar.com/clc1005 rev 2d overdrive recovery for an amplifer, an overdrive condition occurs when the output and/or input ranges are exceeded. the recovery time varies based on whether the input or output is overdriven and by how much the ranges are exceeded. the clc1005, clc1015, and clc2005 will typically recover in less than 20ns from an overdrive condition. figure 6 shows the clc2005 in an overdriven condition. input voltage (0.5v/div) time (20ns/div) output input r l = 2k v in =2v pp g = 5 r f = 1k figure 6: overdrive recovery enable/disable function the clc1015 offers an active-low disable pin that can be used to lower its supply current. leave the pin foating to enable to part. pull the disable pin to the negative supply (which is ground in a single supply application) to disable the output. during the disable condition, the nominal supply current will drop below 127a and the output will be at a high impedance with about 2pf capacitance. power dissipation power dissipation should not be a factor when operating under the stated 2k load condition. however, applications with low impedance, dc coupled loads should be analyzed to ensure that maximum allowed junction temperature is not exceeded. guidelines listed below can be used to verify that the particular application will not cause the device to operate beyond its intended operating range. maximum power levels are set by the absolute maximum junction rating of 150c. to calculate the junction temperature, the package thermal resistance value theta ja ( ja ) is used along with the total die power dissipation. t junction = t ambient + ( ja p d ) where t ambient is the temperature of the working environment. in order to determine p d , the power dissipated in the load needs to be subtracted from the total power delivered by the supplies. p d = p supply - p load supply power is calculated by the standard power equation. p supply = v supply i rmssupply v supply = v s+ - v s- power delivered to a purely resistive load is: p load = ((v load ) rms 2 )/rload eff the effective load resistor (rload eff ) will need to include the effect of the feedback network. for instance, rload eff in figure 3 would be calculated as: r l || (r f + r g ) these measurements are basic and are relatively easy to perform with standard lab equipment. for design purposes however, prior knowledge of actual signal levels and load impedance is needed to determine the dissipated power. here, p d can be found from p d = p quiescent + p dynamic - p load quiescent power can be derived from the specifed i s values along with known supply voltage, v supply . load power can be calculated as above with the desired signal amplitudes using: (v load ) rms = v peak / 2 ( i load ) rms = ( v load ) rms / rload eff the dynamic power is focused primarily within the output stage driving the load. this value can be calculated as: p dynamic = (v s+ - v load ) rms ( i load ) rms assuming the load is referenced in the middle of the power rails or v supply /2. the clc1015 is short circuit protected. however, this may not guarantee that the maximum junction temperature (+150c) is not exceeded under all conditions. figure 7 shows the maximum safe power dissipation in the package vs. the ambient temperature for the packages available. clc1005, clc1015, clc2005
? 2007-2015 exar corporation 14 / 19 exar.com/clc1005 rev 2d 0 0.5 1 1.5 -40 -20 0 20 40 60 80 maximum power dissipation (w) ambient temperature ( c) msop -8 soic -8 tsot -5 tsot -6 figure 7. maximum power derating driving capacitive loads increased phase delay at the output due to capacitive loading can cause ringing, peaking in the frequency response, and possible unstable behavior. use a series resistance, r s , between the amplifer and the load to help improve stability and settling performance. refer to figure 8. + - r f input output r g r s c l r l figure 8. addition of r s for driving capacitive loads table 1 provides the recommended r s for various capacitive loads. the recommended r s values result in approximately <1db peaking in the frequency response. c l (pf) r s () -3db bw (mhz) 22pf 0 118 47pf 15 112 100pf 15 91 492pf 6.5 59 table 1: recommended r s vs. c l for a given load capacitance, adjust r s to optimize the tradeoff between settling time and bandwidth. in general, reducing r s will increase bandwidth at the expense of additional overshoot and ringing. layout considerations general layout and supply bypassing play major roles in high frequency performance. exar has evaluation boards to use as a guide for high frequency layout and as an aid in device testing and characterization. follow the steps below as a basis for high frequency layout: include 6.8f and 0.1f ceramic capacitors for power supply decoupling place the 6.8f capacitor within 0.75 inches of the power pin place the 0.1f capacitor within 0.1 inches of the power pin remove the ground plane under and around the part, especially near the input and output pins to reduce parasitic capacitance minimize all trace lengths to reduce series inductances refer to the evaluation board layouts below for more information. evaluation board information the following evaluation boards are available to aid in the testing and layout of these devices: evaluation board # products ceb002 clc1005 and clc1015 in tsot ceb003 clc1005 in soic ceb006 clc2005 in soic ceb010 clc2005 in msop evaluation board schematics evaluation board schematics and layouts are shown in figures 9-18. these evaluation boards are built for dual- supply operation. follow these steps to use the board in a single-supply application: 1. short -v s to ground. 2. use c3 and c4, if the -v s pin of the amplifer is not directly connected to the ground plane. clc1005, clc1015, clc2005
? 2007-2015 exar corporation 15 / 19 exar.com/clc1005 rev 2d figure 9. ceb002 and ceb003 schematic figure 10. ceb002 top view figure 11. ceb002 bottom view figure 12. ceb003 top view figure 13. ceb003 bottom view clc1005, clc1015, clc2005
? 2007-2015 exar corporation 16 / 19 exar.com/clc1005 rev 2d figure 14. ceb006 & ceb010 schematic figure 15. ceb006 top view figure 16. ceb006 bottom view figure 17. ceb010 top view figure 18. ceb010 bottom view clc1005, clc1015, clc2005
? 2007-2015 exar corporation 17 / 19 exar.com/clc1005 rev 2d mechanical dimensions tsot-6 package tsot-5 package clc1005, clc1015, clc2005
? 2007-2015 exar corporation 18 / 19 exar.com/clc1005 rev 2d msop-8 package soic-8 package clc1005, clc1015, clc2005
for further assistance: email: c ustomersupport@exar.com or hpatechsupport@exar.com exar technical documentation: http://www.exar.com/techdoc/ exar corporation headquarters and sales offices 48760 kato road tel.: +1 (510) 668-7000 fremont, ca 94538 - usa fax: +1 (510) 668-7001 ? 2007-2015 exar corporation 19 / 19 exar.com/clc1005 rev 2d ordering information part number package green operating temperature range packaging clc1005 ordering information clc1005ist5x tsot-5 ye s -40c to +85c tape & reel clc1005ist5mtr tsot-5 ye s -40c to +85c mini tape & reel clc1005ist5evb evaluation board n/a n/a n/a clc1005iso8x soic-8 ye s -40c to +85c tape & reel clc1005iso8mtr soic-8 ye s -40c to +85c mini tape & reel clc1005iso8evb evaluation board n/a n/a n/a clc1015 ordering information clc1015ist6x tsot-6 ye s -40c to +85c tape & reel clc1015ist6mtr tsot-6 ye s -40c to +85c mini tape & reel clc1015ist6evb evaluation board n/a n/a n/a clc2005 ordering information clc2005iso8x soic-8 ye s -40c to +85c tape & reel clc2005iso8mtr soic-8 ye s -40c to +85c mini tape & reel clc2005iso8evb evaluation board n/a n/a n/a CLC2005IMP8X msop-8 ye s -40c to +85c tape & reel clc2005imp8mtr msop-8 ye s -40c to +85c mini tape & reel clc2005imp8evb evaluation board n/a n/a n/a moisture sensitivity level for all parts is msl-1. mini tape and reel quantity is 250. revision history revision date description 2d (ecn 1513-01) march 2015 reformat into exar data sheet template. updated ordering information table to include mtr and evb part numbers. updated thermal resistance numbers and package outline drawings. added clc1015 back into data sheet. notice exar corporation reserves the right to make changes to the products contained in this publication in order to improve design, performance or reliability. exar corporation assumes no responsibility for the use of any circuits described herein, conveys no license under any patent or other right, and makes no representation that the circuits are free of patent infringement. charts and schedules contained here in are only for illustration purposes and may vary depending upon a users specifc application. while the information in this publication has been carefully checked; no responsibility, however, is assumed for inaccuracies. exar corporation 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 signifcantly affect its safety or effectiveness. products are not authorized for use in such applications unless exar corporation receives, in writing, assurances to its satisfaction that: (a) the risk of injury or damage has been minimized; (b) the user assumes all such risks; (c) potential liability of exar corporation is adequately protected under the circumstances. reproduction, in part or whole, without the prior written consent of exar corporation is prohibited. clc1005, clc1015, clc2005


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