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| ________________general description the max4200?ax4205 are ultra-high-speed, open- loop buffers featuring high slew rate, high output cur- rent, low noise, and excellent capacitive-load-driving capability. the max4200/max4201/max4202 are sin- gle buffers, while the max4203/max4204/max4205 are dual buffers. the max4201/max4204 have integrated 50 ? termination resistors, making them ideal for driv- ing 50 ? transmission lines. the max4202/max4205 include 75 ? back-termination resistors for driv- ing 75 ? transmission lines. the max4200/max4203 have no internal termination resistors. the max4200?ax4205 use a proprietary architecture to achieve up to 780mhz -3db bandwidth, 280mhz 0.1db gain flatness, 4200v/? slew rate, and ?0ma output current drive capability. they operate from ?v supplies and draw only 2.2ma of quiescent current. these features, along with low-noise performance, make these buffers suitable for driving high-speed analog-to- digital converter (adc) inputs or for data-communica- tions applications. ________________________applications high-speed dac buffers wireless lans digital-transmission line drivers high-speed adc input buffers if/communications systems ____________________________features ? 2.2ma supply current ? high speed 780mhz -3db bandwidth (max4201/max4202) 280mhz 0.1db gain flatness (max4201/max4202) 4200v/ � s slew rate ? low 2.1nv/ hz voltage-noise density ? low 0.8pa/ hz current-noise density ? high 90ma output drive (max4200/max4203) ? excellent capacitive-load-driving capability ? available in space-saving sot23 or � ma x ? packages max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers ________________________________________________________________ maxim integrated products 1 19-1338; rev 3; 3/07 _______________ordering information ___________t ypical application circuit max4201 r ext * 50 ? * r l = r t + r ext r t * 50 ? 50 ? cable outin coaxial cable driver part pin-package top mark pkg code max4200 esa 8 so � s8-2 max4200euk-t 5 sot23-5 aabz u5-1 max4201 esa 8 so � s8-2 max4201euk-t 5 sot23-5 abaa u5-1 max4202 esa 8 so � s8-2 max4202euk-t 5 sot23-5 abab u5-1 max4203 esa 8 so � s8-2 max4203eua-t 8 ?ax-8 � u8-1 max4204 esa 8 so � s8-2 max4204eua-t 8 ?ax-8 � u8-1 max4205 esa 8 so � s8-2 max4205eua-t 8 ?ax-8 � u8-1 part no. of buffers internal output termination ( ? ) pin-package max4204 2 50 8 so/?ax max4200 1 � 8 so, 5 sot23 max4201 1 50 8 so, 5 sot23 max4205 2 75 8 so/?ax max4202 1 75 8 so, 5 sot23 max4203 2 � 8 so/?ax ___________________________ selector guide pin configurations appear at end of data sheet. for pricing, delivery, and ordering information, please contact maxim/dallas direct! at 1-888-629-4642, or visit maxim? website at www.maxim-ic.com. ?ax is a registered trademark of maxim integrated products, inc. note: all devices are specified over the -40? to +85? operating temperature range.
max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers 2 _______________________________________________________________________________________ absolute maximum ratings dc electrical characteristics (v cc = +5v, v ee = -5v, r l = , t a = t min to t max , unless otherwise noted. typical values are at t a = +25?.) stresses beyond those listed under ?bsolute maximum ratings?may cause permanent damage to the device. these are stress rating s only, and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of the specificatio ns is not implied. exposure to absolute maximum rating conditions for extended periods may affect device reliability. supply voltage (v cc to v ee )................................................+12v voltage on any pin to gnd..............(v ee - 0.3v) to (v cc + 0.3v) output short-circuit duration to gnd........................continuous continuous power dissipation (t a = +70?) 5-pin sot23 (derate 7.1mw/? above +70?).............571mw 8-pin ?ax (derate 4.1mw/? above +70?) ..............330mw 8-pin so (derate 5.9mw/? above +70?)...................471mw operating temperature range ...........................-40? to +85? storage temperature range .............................-65? to +150? lead temperature (soldering, 10s) .................................+300? v in = 0v sinking or sourcing per buffer, v in = 0v guaranteed by psr test r l = 30 ? v s = ?v to ?.5v -3.0v v out 3.0v f = dc v in = 0v max4203/max4204/max4205 (note 1) conditions ma 75 i sc short-circuit output current 90 150 ma ?4 i out output current ?2 ?0 ? 75 r out output resistance 50 8 mv 115 v os input offset voltage ma 2.2 4 i s v ? ?.5 v s operating supply voltage quiescent supply current db 55 72 psr power-supply rejection v/v 0.41 0.50 0.59 a v voltage gain 0.42 0.50 0.58 0.9 0.96 1.1 ?/? 20 tcv os input offset voltage drift mv 0.4 input offset voltage matching ? 0.8 10 i b input bias current k ? 500 r in input resistance units min typ max symbol parameter max4200/max4203, r ext = 150 ? max4201/max4204, r ext = 50 ? max4202/max4205, r ext = 75 ? max4200/max4203 max4201/max4204 max4202/max4205 max4200/max4203 max4201/max4204 max4202/max4205 max4200/max4203 max4201/max4204 max4202/max4205 max4200/max4203 r l = 150 ? v v out output-voltage swing ?.3 ?.8 r l = 100 ? ?.2 ?.7 r l = 37.5 ? ?.3 max4201/max4204 r l = 50 ? ?.9 ?.1 max4202/max4205 r l = 75 ? ?.0 ?.3 v out = 2vp-p max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers _______________________________________________________________________________________ 3 v out = 2v p-p v out 100mv rms v out 100mv rms v out = 2v step conditions dbc -32 sfdr spurious-free dynamic range -44 -47 -34 -45 -48 ns 12 t s settling time to 0.1% ps 405 group delay time 530 780 660 mhz 310 fpbw full-power bandwidth 490 mhz 230 bw (0.1db) 0.1db bandwidth mhz 720 bw (-3db) -3db bandwidth 220 280 130 units min typ max symbol parameter ac electrical characteristics (v cc = +5v, v ee = -5v, r l = 100 ? for max4200/max4201/max4203/max4204, r l = 150 ? for max4202/max4205, t a = t min to t max , unless otherwise noted. typical values are at t a = +25?.) f = 1mhz max4200/max4201/ max4202, f = 500khz, v out = 2v p-p pa/ hz 0.8 i n input current-noise density -48 -48 -72 pf 2 c in input capacitance v out = 2v p-p f = 10mhz -65 x talk amplifier crosstalk db -87 ? 6 z out output impedance max4200 max4201/max4202 max4203 max4204/max4205 max4200 max4201/max4202 max4203 max4204/max4205 max4200/max4201/max4202 max4200/max4201/ max4202 f = 5mhz f = 20mhz f = 100mhz f = 5mhz f = 20mhz f = 100mhz max4203/max4204/ max4205 v out 2v p-p v out = 2v step v/? 4200 sr slew rate max4203/max4204/max4205 f = 1mhz ntsc, r l = 150 ? ntsc, r l = 150 ? nv/ hz 2.1 e n input voltage-noise density degrees 0.15 dp differential phase error % 1.3 dg differential gain error second harmonic third harmonic total harmonic second harmonic third harmonic total harmonic max4203/max4204/| max4205, f = 500khz, v out = 2v p-p dbc -47 hd harmonic distortion -47 -83 f = 10mhz f = 100mhz note 1: tested with no load; increasing load will decrease input impedance. max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers 4 _______________________________________________________________________________________ __________________________________________typical operating characteristics (v cc = +5v, v ee = -5v, r l = 100 ? for max4200/max4201/max4203/max4204, r l = 150 ? for max4202/max4205, unless otherwise noted.) 4 -6 100k 1m 10m 100m 1g max4200 small-signal gain vs. frequency -4 -5 -3 max4200/25-01 frequency (hz) normalized gain (db) -2 -1 0 2 1 3 v out = 100mv p-p 4 -6 100k 1m 10m 100m 1g max4201/max4202 small-signal gain vs. frequency -4 -5 -3 max4200/25-02 frequency (hz) normalized gain (db) -2 -1 0 2 1 3 v out = 100mv p-p 4 -6 100k 1m 10m 100m 1g max4200/max4201/max4202 large-signal gain vs. frequency -4 -5 -3 max4200/25-03 frequency (hz) normalized gain (db) -2 -1 0 2 1 3 v out = 2v p-p 4 -6 100k 1m 10m 100m 1g max4203 small-signal gain vs. frequency -4 -5 -3 max4200/25-04 frequency (hz) normalized gain (db) -2 -1 0 2 1 3 v out = 100mv p-p 5 -5 100k 1m 10m 100m 1g 10g group delay vs. frequency -3 -4 -2 max4200/25-07 frequency (hz) group delay (ns) -1 0 1 3 2 4 4 -6 100k 1m 10m 100m 1g 10g max4204/max4205 small-signal gain vs. frequency -4 -5 -3 max4200/25-05 frequency (hz) normalized gain (db) -2 -1 0 2 1 3 v out = 100mv p-p 4 -6 100k 1m 10m 100m 1g max4203/max4204/max4205 large-signal gain vs. frequency -4 -5 -3 max4200/25-06 frequency (hz) normalized gain (db) -2 -1 0 2 1 3 v out = 2v p-p 0 -100 100k 1m 10m 100m 1g 10g power-supply rejection vs. frequency -80 -90 -70 max4200/25-08 frequency (hz) psr (db) -60 -50 -40 -20 -30 -10 9000 0 0 1.0 3.0 2.5 5.0 slew rate vs. output voltage 3000 2000 1000 4000 7000 8000 max4200/4205-09 output voltage (vp-p) slew rate (v / s) 1.5 2.0 0.5 3.5 5000 6000 4.0 4.5 max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers _______________________________________________________________________________________ 5 0 -10 -100 100k 100m 10m 1m max4200/max4201/max4202 harmonic distortion vs. frequency -60 -70 -80 -90 -30 -40 -50 -20 max4200/4205-10 frequency (hz) harmonic distortion (dbc) third harmonic second harmonic v in = 2vp-p 0 -10 -100 100k 100m 10m 1m max4203/max4204/max4205 harmonic distortion vs. frequency -60 -70 -80 -90 -30 -40 -50 -20 max4200/4205-11 frequency (hz) harmonic distortion (dbc) third harmonic second harmonic v out = 2vp-p 100 1 100k 10m 100m 1m 1g max4200/max4203 output impedance vs. frequency max4200/4205-12 frequency (hz) output impedance ( ? ) 10 100 10 100k 10m 100m 1m 1g max4201/max4204 output impedance vs. frequency max4200/4205-13 frequency (hz) output impedance ( ? ) 100 1 1 10 100 1k 10k 100k 1m 10m input voltage-noise density vs. frequency max4200/4205-16 frequency (hz) voltage noise density (nv/ hz) 10 100 10 100k 10m 100m 1m 1g max4202/max4205 output impedance vs. frequency max4200/4205-14 frequency (hz) output impedance ( ? ) 0 -100 100k 1m 10m 100m 1g 10g max4203/max4204/max4205 crosstalk vs. frequency -80 -90 max4200/4205-15 frequency (hz) crosstalk (db) -60 -70 -40 -50 -20 -30 -10 10 0.1 1 10 100 1k 10k 100k 1m 10m input current-noise density vs. frequency max4200/4205-17 frequency (hz) current noise density (pa/ hz) 1.0 -0.05 0 100 0100 differential gain and phase (r l = 150 ? ) -0.5 0 0 0.05 0.5 0.10 1.0 0.20 0.15 1.5 ire diff phase (deg) diff gain (%) max4200/4205-18 _________________________________t ypical operating characteristics (continued) (v cc = +5v, v ee = -5v, r l = 100 ? for max4200/max4201/max4203/max4204, r l = 150 ? for max4202/max4205, unless otherwise noted.) max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers 6 _______________________________________________________________________________________ _________________________________t ypical operating characteristics (continued) (v cc = +5v, v ee = -5v, r l = 100 ? for max4200/max4201/max4203/max4204, r l = 150 ? for max4202/max4205, unless otherwise noted.) 0 4 2 8 6 12 10 14 -5 -3 -2 -4 -1012345 gain error vs. input voltage max4200-19 input voltage (v) gain error (%) r l = 100 ? r l = 150 ? 1 3 2 6 5 4 9 8 7 10 0 150 200 50 100 250 300 350 400 output voltage swing vs. external load resistance max4200-20 external load resistance ( ? ) output voltage swing (v p-p ) max4200/4203 max4201/4204 max4202/4205 in voltage 50mv/div out gnd gnd time (5ns/div) small-signal pulse response max4200-21 in voltage 50mv/div out gnd gnd time (5ns/div) max4200/max4203 small-signal pulse response max4200-22 c load = 15pf in voltage 50mv/div out gnd gnd time (5ns/div) max4201/max4202/max4204/max4205 small-signal pulse response max4200-23 c load = 22pf in voltage 1v/div out gnd gnd time (5ns/div) large-signal pulse response max4200-24 max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers _______________________________________________________________________________________ 7 -5 -2 -3 -4 -1 0 1 2 3 4 5 -40 10 -15 356085 input offset voltage vs. temperature max4200-28 temperature (?) input offset voltage (mv) -5 -2 -3 -4 -1 0 1 2 3 4 5 -40 10 -15 356085 input bias current vs. temperature max4200-29 temperature (?) input bias current ( a) 3.0 3.2 3.6 3.4 3.8 4.0 -40 10 -15 356085 max4200/max4203 output voltage swing vs. temperature max4200-30 temperature (?) voltage swing (vp-p) r l = 100 ? r l = 150 ? _________________________________t ypical operating characteristics (continued) (v cc = +5v, v ee = -5v, r l = 100 ? for max4200/max4201/max4203/max4204, r l = 150 ? for max4202/max4205, unless otherwise noted.) in voltage 1v/div out gnd gnd time (5ns/div) max4200/max4203 large-signal pulse response max4200-25 c load = 15pf in voltage 1v/div out gnd gnd time (5ns/div) max4201/max4202/max4204/max4205 large-signal pulse response max4200-26 c load = 22pf 1.0 2.0 1.5 3.0 2.5 3.5 4.0 -40 10 -15 356085 supply current (per buffer) vs. temperature max4200-27 temperature (?) supply current (ma) _______________detailed description the max4200?ax4205 wide-band, open-loop buffers feature high slew rates, high output current, low 2.1nv hz voltage-noise density, and excellent capaci- tive-load-driving capability. the max4200/max4203 are single/dual buffers with up to 660mhz bandwidth, 230mhz 0.1db gain flatness, and a 4200v/? slew rate. the max4201/max4204 single/dual buffers with inte- grated 50 ? output termination resistors, up to 780mhz bandwidth, 280mhz gain flatness, and a 4200v/? slew rate, are ideally suited for driving high-speed signals over 50 ? cables. the max4202/max4205 provide bandwidths up to 720mhz, 230mhz gain flatness, 4200v/? slew rate, and integrated 75 ? output termina- tion resistors for driving 75 ? cables. with an open-loop gain that is slightly less than +1v/v, these devices do not have to be compensated with the internal dominant pole (and its associated phase shift) that is present in voltage-feedback devices. this fea- ture allows the max4200?ax4205 to achieve a nearly constant group delay time of 405ps over their full fre- quency range, making them well suited for a variety of rf and if signal-processing applications. these buffers operate with ?v supplies and consume only 2.2ma of quiescent supply current per buffer while providing up to ?0ma of output current drive capability. __________applications information power supplies the max4200?ax4205 operate with dual supplies from ?v to ?.5v. both v cc and v ee should be bypassed to the ground plane with a 0.1? capacitor located as close to the device pin as possible. layout techniques maxim recommends using microstrip and stripline tech- niques to obtain full bandwidth. to ensure that the pc board does not degrade the amplifier? performance, design it for a frequency greater than 6ghz. pay care- ful attention to inputs and outputs to avoid large para- sitic capacitance. whether or not you use a constant-impedance board, observe the following guidelines when designing the board: ? do not use wire-wrap boards, because they are too inductive. ? do not use ic sockets, because they increase para- sitic capacitance and inductance. max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers 8 _______________________________________________________________________________________ ______________________________________________________________pin description no connection. not internally connected n.c. 1 1, 2, 5, 8 � buffer input in 3 3 � buffer 1 input in1 � � 1 buffer 1 output out1 � � 2 negative power supply v ee 2 4 � negative power supply for buffer 1 v ee1 � � 3 negative power supply for buffer 2 v ee2 � � 4 buffer 2 input in2 � � 5 buffer 2 output out2 � � 6 buffer output out 5 6 � positive power supply v cc 4 7 � positive power supply for buffer 2 v cc2 � � 7 positive power supply for buffer 1 v cc1 � � 8 name function sot23-5 so so/max max4200/max4201/max4202 pin max4203 max4204 max4205 max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers _______________________________________________________________________________________ 9 ? use surface-mount instead of through-hole compo- nents for better high-frequency performance. ? use a pc board with at least two layers; it should be as free from voids as possible. ? keep signal lines as short and as straight as possi- ble. do not make 90� turns; round all corners. input impedance the max4200?ax4205 input impedance looks like a 500k ? resistor in parallel with a 2pf capacitor. since these devices operate without negative feedback, there is no loop gain to transform the input impedance upward, as in closed-loop buffers. as a consequence, the input impedance is directly related to the output impedance. if the output load impedance decreases, the input impedance also decreases. inductive input sources (such as an unterminated cable) may react with the input capacitance and produce some peaking in the buffer? frequency response. this effect can usu- ally be minimized by using a properly terminated trans- mission line at the buffer input, as shown in figure 1. output current and gain sensitivity the absence of negative feedback means that open- loop buffers have no loop gain to reduce their effective output impedance. as a result, open-loop devices usu- ally suffer from decreasing gain as the output current is decreased. the max4200?ax4205 include local feedback around the buffer? class-ab output stage to ensure low output impedance and reduce gain sensitiv- ity to load variations. this feedback also produces demand-driven current bias to the output transistors for ?0ma (max4200/max4203) drive capability that is rel- atively independent of the output voltage (see typical operating characteristics ). output capacitive loading and stability the max4200?ax4205 provide maximum ac perfor- mance with no load capacitance. this is the case when the load is a properly terminated transmission line. however, these devices are designed to drive any load capacitance without oscillating, but with reduced ac per- formance. since the max4200?ax4205 operate in an open-loop configuration, there is no negative feedback to be transformed into positive feedback through phase shift introduced by a capacitive load. therefore, these devices will not oscillate with capacitive loading, unlike similar buffers operating in a closed-loop configuration. however, a capacitive load reacting with the buffer? output impedance can still affect circuit performance. a capacitive load will form a lowpass filter with the buffer? output resistance, thereby limiting system bandwidth. with higher capacitive loads, bandwidth is dominated by the rc network formed by r t and c l ; the bandwidth of the buffer itself is much higher. also note that the isolation resistor forms a divider that decreases the voltage delivered to the load. another concern when driving capacitive loads results from the amplifier? output impedance, which looks inductive at high frequency. this inductance forms an l-c resonant circuit with the capacitive load and caus- es peaking in the buffer? frequency response. figure 2 shows the frequency response of the max4200/max4203 under different capacitive loads. to settle out some of the peaking, the output requires an iso- lation resistor like the one shown in figure 3. figure 4 is a plot of the max4200/max4203 frequency response with capacitive loading and a 10 ? isolation resistor. in many applications, the output termination resistors included in the max4201/max4202/ max4204/max4205 will serve this purpose, reducing component count and board space. figure 5 shows the max4201/max4202/ max4204/max4205 frequency response with capacitive loads of 47pf, 68pf, and 120pf. coaxial cable drivers coaxial cable and other transmission lines are easily dri- ven when properly terminated at both ends with their characteristic impedance. driving back-terminated transmission lines essentially eliminates the line? capaci- tance. the max4201/max4204, with their integrated 50 ? output termination resistors, are ideal for driving 50 ? cables. the max4202/max4205 include integrated 75 ? termination resistors for driving 75 ? cables. note that the output termination resistor forms a voltage divider with the load resistance, thereby decreasing the amplitude of the signal at the receiving end of the cable by one half (see the typical application circuit) . max42_ _ r l 50 ? * max4201/4202/4204/4205 only r t * 50 ? coax source figure 1. using a properly terminated input source max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers 10 ______________________________________________________________________________________ 5 -5 100k 1m 10m 100m 1g -3 -4 -2 max4200-fig02 frequency (hz) gain (db) -1 0 1 3 2 4 c l = 47pf v out = 100mv p-p c l = 68pf c l = 120pf c l = 220pf figure 2. max4200/max4203 small-signal gain vs. frequency with load capacitance and no isolation resistor max4200 max4203 r iso c l v in v out figure 3. driving a capacitive load through an isolation resistor 5 -5 100k 1m 10m 100m 1g -3 -4 -2 max4200-fig04 frequency (hz) gain (db) -1 0 1 3 2 4 c l = 47pf c l = 68pf c l = 120pf r iso = 10 ? v out = 100mv p-p figure 4. max4200/max4203 small-signal gain vs. frequency with load capacitance and 10 ? isolation resistor 5 -5 100k 1m 10m 100m 1g -3 -4 -2 max4200-fig05 frequency (hz) gain (db) -1 0 1 3 2 4 c l = 47pf c l = 68pf c l = 120pf v out = 100mv p-p figure 5. max4201/max4202/max4204/max4205 small- signal gain vs. frequency with capacitive load and no external isolation resistor max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers ______________________________________________________________________________________ 11 __________________________________________________________pin configurations top view n.c. = not internally connected * r t = 0 ? (max4200/max4203) r t = 50 ? (max4201/max4204) r t = 75 ? (max4202/max4205) out2 v ee1 in2 v ee2 1 2 v cc1 v cc2 out1 in1 max4203 max4204 max4205 max4200 max4201 max4202 max4200 max4201 max4202 so/ max 3 4 out in n.c. v ee 1 2 8 7 n.c. v cc n.c. n.c. so 3 4 6 5 v ee v cc in 1 5 out n.c. sot23-5 2 3 4 *r t *r t *r t *r t 8 7 6 5 ___________________chip information transistor counts: max4200/max4201/max4202: 33 max4203/max4204/max4205: 67 substrate connected to v ee max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers 12 ______________________________________________________________________________________ package information (the package drawing(s) in this data sheet may not reflect the most current specifications. for the latest package outline info rmation go to www.maxim-ic.com/packages .) soicn .eps package outline, .150" soic 1 1 21-0041 b rev. document control no. approval proprietary information title: top view front view max 0.010 0.069 0.019 0.157 0.010 inches 0.150 0.007 e c dim 0.014 0.004 b a1 min 0.053 a 0.19 3.80 4.00 0.25 millimeters 0.10 0.35 1.35 min 0.49 0.25 max 1.75 0.050 0.016 l 0.40 1.27 0.394 0.386 d d min dim d inches max 9.80 10.00 millimeters min max 16 ac 0.337 0.344 ab 8.75 8.55 14 0.189 0.197 aa 5.00 4.80 8 n ms012 n side view h 0.244 0.228 5.80 6.20 e 0.050 bsc 1.27 bsc c h e e b a1 a d 0 -8 l 1 variations: max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers ______________________________________________________________________________________ 13 package information (continued) (the package drawing(s) in this data sheet may not reflect the most current specifications. for the latest package outline info rmation go to www.maxim-ic.com/packages .) sot-23 5l .eps max4200?ax4205 ultra-high-speed, low-noise, low-power, sot23 open-loop buffers maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a maxim product. no circu it patent licenses are implied. maxim reserves the right to change the circuitry and specifications without notice at any time. 14 ____________________maxim integrated products, 120 san gabriel drive, sunnyvale, ca 94086 408-737-7600 � 2007 maxim integrated products is a registered trademark of maxim integrated products, inc. 8lumaxd.eps package outline, 8l umax/usop 1 1 21-0036 j rev. document control no. approval proprietary information title: max 0.043 0.006 0.014 0.120 0.120 0.198 0.026 0.007 0.037 0.0207 bsc 0.0256 bsc a2 a1 c e b a l front view side view e h 0.60.1 0.60.1 ?0.500.1 1 top view d 8 a2 0.030 bottom view 1 6 s b l h e d e c 0 0.010 0.116 0.116 0.188 0.016 0.005 8 4x s inches - a1 a min 0.002 0.95 0.75 0.5250 bsc 0.25 0.36 2.95 3.05 2.95 3.05 4.78 0.41 0.65 bsc 5.03 0.66 6 0 0.13 0.18 max min millimeters - 1.10 0.05 0.15 dim package information (continued) (the package drawing(s) in this data sheet may not reflect the most current specifications. for the latest package outline info rmation go to www.maxim-ic.com/packages .) revision history pages changed at rev 3: 1?, 8, 10?4 |
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