page 1 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com + 100% pin - to - pin drop - in replacement to quartz and mems based xo + high temperature low power oscillator for low cost + excellent long time reliability - outperforms quartz - based xo + operating temperature from - 40c to 125c / - 55c to 125c optional + supply voltage of 1.8v, 2.5v to 3.3vdc + excellent total frequency stability as low as 20 ppm + lvcmos/lvttl compatible output + express samples within 1 day ex works petermann - technik + pb - free, rohs and reach compliant / msl1@260c applications general data [1,2] note: 1. all electrical specifications in the above table are specified with 15 pf output load at default drive strength and for all v dd (s) unless otherwise stated. 2. the t ypical val u e of any p arame t er i n t h e elec t rical ch a ract e rist i c t able is speci f ied f or t he n ominal v a lue of t he hi g hest vol t age o pt i on f or t hat pa rame t er a nd at 25 c t emper a tu r e. features + all high temperature applications for C 40/+125c (non aeq - q100 automotive and avionics) parameter and conditions symbol min. typ. max. unit condition frequency range output frequency range f 1 C 110 mhz frequency stability and aging frequency stability f_stab - 20 C +20 ppm inclusive of initial tolerance at 25c, 1st year aging at 25c, - 25 C +25 ppm and variations over operating temperature, rated power - 30 C +30 ppm supply voltage and load (15 pf 10%). - 50 C +50 ppm operating temperature range operating temperature range t_use - 40 C +105 c - 40 C +125 c storage temperature range t_stor - 55 C +125 c storage supply voltage and current consumption supply voltage v dd 1.62 1.8 1.98 v 2.25 2.5 2.75 v 2.52 2.8 3.08 v 2.7 3.0 3.3 v 2.97 3.3 3.63 v 2.25 C 3.63 v current consumption i dd C 3.8 4.5 ma no load condition, f = 20 mhz, v dd = 2.8v, 3.0v, or 3.3v C 3.6 4.2 ma no load condition, f = 20 mhz, v dd = 2.5v C 3.4 4 ma no load condition, f = 20 mhz, v dd = 1.8v oe disable current i_ od C C 4.1 ma v dd = 2.5v to 3.3v, oe = low, output in high z state C C 3.8 ma v dd = 1.8v, oe = low, output in high z state standby current i_std C 2.6 8.5 a v dd = 2.8v to 3.3 v , st = lo w , output is pulled down C 1.4 5.5 a v dd = 2.5 v , st = lo w , output is pulled down C 0.6 3.5 a v dd = 1.8 v , st = lo w , output is pulled down high temperature low power oscillator series ?htlpo 1.0 110.0 mh z
page 2 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com general data [1] (continued) note: 1. all electrical specifications in the above table are specified with 15 pf output load and for all v dd (s) unless otherwise stated. p in description pin symbol functionality 1 output enable h (3) : specified frequency output l: output is high impedance. only output driver is disabled. oe/ st/nc standby h [3]: specified frequency output l: output is low (weak pull down). device goes to sleep mode. supply current reduces to i_std. no connect any vol t age between 0 and v dd or open [3] : s pecified fre- quency output. pin 1 has no function. 2 gnd power electrical ground [4] 3 out output oscillator output 4 v dd power power supply voltage [4] note: 3. i n oe or st mod e , a pull - up resist o r of 10k? o r l e ss is r ecommend e d if pin 1 is not e x t er n ally d riven. if p in 1 n eeds to be l e f t f loa t in g , use t h e nc op t io n . 4. a capacitor value of 0.1 f between vdd and gnd is required. 1 gnd 2 3 4 oe/st/nc out vdd top view parameter and conditions symbol min. typ . max. unit condition lvcmos output characteristics duty cycle dc 45 C 55 % all v dd s rise/fall time tr, tf C 1.0 2.0 ns v dd = 2.5v, 2.8v, 3.0v or 3.3v, 20% - 80% C 1.3 2.5 ns v dd =1.8v, 20% - 80% C 1.0 3.0 ns v dd = 2.25v - 3.63v, 20% - 80% output high voltage voh 90% C C v dd ioh = - 4 ma (v dd = 3.0v or 3.3v) ioh = - 3 ma (v dd = 2.8v and v dd = 2.5v) ioh = - 2 ma (v dd = 1.8v) output low voltage vol C C 10% v dd iol = 4 ma (v dd = 3.0v or 3.3v) iol = 3 ma (v dd = 2.8v and v dd = 2.5v) iol = 2 ma (v dd = 1.8v) input characteristics input high voltage vih 70% C C v dd pin 1, oe or st input low voltage vil C C 30% v dd pin 1, oe or st input pull - up impedence z_in 50 87 150 k? pin 1, oe logic high or logic low, or st logic high 2 C C m? pin 1, st logic low startup and resume timing startup time t_start C C 5 ms measured from the time v dd reaches 90% of final value enable/disable time t_oe C C 130 ns f = 110 mhz. for other frequencies, t_oe = 100 ns + 3* clock periods resume time t_resume C C 5 ms measured from the time st pin crosses 50% threshold jitter rms period jitter t_jitt C 1.6 2.5 ps f = 75 mhz, v dd = 2.5v, 2.8v, 3.0v or 3.3v C 1.9 3 ps f = 75 mhz, v dd = 1.8v peak - to - peak period jitter t_pk C 12 20 ps f = 75 mhz, v dd = 2.5v, 2.8v, 3.0v or 3.3v C 14 30 ps f = 75 mhz, v dd = 1.8v rms phase jitter (random ) t_phj C 0.5 0.8 ps f = 75 mhz, integration bandwidth = 900 khz to 7.5 mhz C 1.3 2 ps f = 75 mhz, integration bandwidth = 12 khz to 20 mhz excellent reliability data mtbf 500 million hours shock resistance: 10.000 g vibration resistance: 70 g
page 3 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com period low pulse (tl) high pulse (th) 20%v dd 80%v dd 50% tr tf clk output t_resume v dd st voltage 50%v dd t_resume: time to resume from st v dd t_oe clk output oe voltage t_oe: time to re - enable the clock output 50%v dd t est circuit and waveform 1k ? v dd vout test point 4 1 3 2 v dd power supply 0.1f oe/st function 15pf (including probe and fixture capacitance) timing diagrams note: 5. htlpo h a s no r u n t p ulses a nd no gl i tch ou t p u t dur i ng s t ar t up or resum e . figure 1. t est circuit figure 2. waveform figure 3. startup timing (oe/st mode) figure 4. standby resume timing (st mode only) figure 5. oe enable timing (oe mode only) figure 6. oe disable timing (oe mode only) 90%v dd v dd t_start no glitch during start up (5) clk output pin 4 voltage t_start: time to start from power - off t_oe: time to put the output drive in high z mode t_oe clk output v dd oe voltage 50%v dd hz
page 4 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com the htlpo includes a programmable drive strength feature to provi- de a simple, flexible tool to optimize the clock rise/fall time for spe- cific applications. benefits from the programmable drive strength feature are: + improves system radiated electromagnetic interference (emi) by slowing down the clock rise/fall time + improves the downstream clock receivers (rx) jitter by de - creasing (speeding up) the clock rise/fall time. + ability to drive large capacitive loads while maintaining full swing with sharp edge rates. for more detailed information about rise/fall time control and drive strength selection, please contact petermann - technik application engineers. emi reduction by slo wing rise/fall time figure 7 shows the harmonic power reduction as the rise/fall times are increased (slowed down). the rise/fall times are expressed as a ratio of the clock period. for the ratio of 0.05, the signal is very close to a square wave. for the ratio of 0.45, the rise/fall times are very close to near - triangular waveform. these results, for example, show that the 11th clock harmonic can be reduced by 35 db if the rise/fall edge is increased from 5% of the period to 45% of the period. jitter reduction wit h faster rise/fall time power supply noise can be a source of jitter for the downstream chip- set. one way to reduce this jitter is to increase rise/fall time (edge rate) of the input clock. some chipsets would require faster rise/fall time in order to reduce their sensitivity to this type of jitter. the htl- po provides up to 3 additional high drive strength settings for very fast rise/fall time. refer to the rise/fall time tables to determine the proper drive strength. max. frequency = 1 5 x trf_20/80 high output load capability the rise/fall time of the input clock varies as a function of the actual capacitive load the clock drives. at any given drive strength, the rise/ fall time becomes slower as the output load increases. as an examp- le, for a 3.3v htlpo device with default drive strength setting, the typical rise/fall time is 1 ns for 15 pf output load. the typical rise/fall time slows down to 2.6 ns when the output load increases to 45 pf. one can choose to speed up the rise/fall time to 1.83ns by then in- creasing the drive strength setting on the htlpo. the htlpo can support up to 60 pf or higher in maximum capacitive loads with drive strength settings. refer to the rise/tall time tables (table 1 to 5) to determine the proper drive strength for the desired combination of output load vs. rise/fall time. htlpo drive strength selection t ables 1 through 5 define the rise/fall time for a given capac itive load and supply voltage. 1. select the table that matches the htlpo nominal supply voltage (1 .8v, 2.5v , 2.8v , 3 . 0v , 3.3v). 2. select the capacitive load column that matches the appli - cation requirement (5 pf to 60 pf) 3. under the capacitive load column, select the desired rise/fall times. 4. the left - most column represents the part number code for the corresponding drive strength. 5. add the drive strength code to the part number for ordering purposes. calculating maximum frequency based on the rise and fall time data given in t ables 1 through 5, the maximum frequency the oscillator can operate with guaranteed full swing of the output voltage over temperature as follows: wh ere t rf_2 0/8 0 i s th e typic al v a lu e fo r 20% - 8 0 % rise/f a ll time. example 1 calculate f max for the following condition: + v dd = 1.8v (table 1) + capacitive load: 30pf + desired tr/f time = 3 ns (rise/fall time part number code=e) part number for the above example: htlpo18 - 2520 - e - 25 - y - 75.000mhz - t - s drive strength code is inserted here. standard setting is s programmable drive s trength harmonic amplitude (db) harmonic number figure 7. harmonic emi reducti on as a function of slower rise/fall tim e 1 3 5 7 9 11 10 trise=0.05 - 80 - 10 0 - 20 - 30 - 40 - 50 - 60 - 70 trise=0.1 trise=0.15 trise=0.2 trise=0.25 trise=3 trise=0.35 trise=0.4 trise=0.45
page 5 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com rise/fall time (20% to 80%) vs c load rise/fall time typ (ns) drive strength \ c load 5 pf 15 pf 30 pf 45 pf 60 pf l 3.39 6.88 11.63 17.56 23 . 59 a 1.74 3.50 6 . 38 8 . 98 12.19 r 1 . 16 2 . 33 4.29 6.04 8.34 b 0 . 81 1 . 82 3.22 4.52 6.33 t or " - ": standard 0 . 46 1 . 00 1.86 2.60 3.84 e 0 . 33 0 . 87 1.64 2.30 3.35 u 0 . 28 0 . 79 1.46 2.05 2.93 f 0 . 25 0 . 72 1.31 1.83 2.61 rise/fall time typ (ns) drive strength \ c load 5 pf 15 pf 30 pf 45 pf 60 pf l 6.16 11.61 22.00 31.27 39.91 a 3.19 6.35 11.00 16.01 21.52 r 2.11 4.31 7.65 10.77 14.47 b 1.65 3.23 5.79 8.18 11.08 t 0.93 1.91 3.32 4.66 6.48 e 0.78 1.66 2.94 4.09 5.74 u 0.70 1.48 2.64 3.68 5.09 s f or standard 0.65 1.30 2.40 3.35 4.56 table 1. vdd = 1.8v rise/fall times for specific c load rise/fall time typ (ns) drive strength \ c load 5 pf 15 pf 30 pf 45 pf 60 pf l 4.13 8.25 12.82 21.45 27.79 a 2.11 4.27 7.64 11.20 14.49 r 1.45 2.81 5.16 7.65 9.88 b 1.09 2.20 3.88 5.86 7.57 t 0.62 1.28 2.27 3.51 4.45 s for standard 0.54 1.00 2.01 3.10 4.01 u 0.43 0.96 1.81 2.79 3.65 f 0.34 0.88 1.64 2.54 3.32 rise/fall time typ (ns) drive strength \ c load 5 pf 15 pf 30 pf 45 pf 60 pf l 3.77 7.54 12.28 19.57 25 . 27 a 1.94 3.90 7 . 03 10.24 13 . 34 r 1 . 29 2 . 57 4.72 7.01 9.06 b 0 . 97 2 . 00 3.54 5.43 6.93 t 0 . 55 1 . 12 2.08 3.22 4.08 s f or standard 0 . 44 1 . 00 1.83 2.82 3.67 u 0 . 34 0 . 88 1.64 2.52 3.30 f 0 . 29 0 . 81 1.48 2.29 2.99 rise/fall time typ (ns) drive strength \ c load 5 pf 15 pf 30 pf 45 pf 60 pf l 3.60 7.21 11.97 18.74 24.30 a 1.84 3.71 6.72 9.86 12.68 r 1.22 2.46 4.54 6.76 8.62 b 0.89 1.92 3.39 5.20 6.64 s f or standard 0.51 1.00 1.97 3.07 3.90 e 0.38 0.92 1.72 2.71 3.51 u 0.30 0.83 1.55 2.40 3.13 f 0.27 0.76 1.39 2.16 2.85 rise/fall time typ (ns) drive strength \ c load 5 pf 15 pf 30 pf 45 pf 60 pf l 3.39 6.88 11.63 17.56 23 . 59 a 1.74 3.50 6 . 38 8 . 98 12.19 r 1 . 16 2 . 33 4.29 6.04 8.34 b 0 . 81 1 . 82 3.22 4.52 6.33 s f or standard 0 . 46 1 . 00 1.86 2.60 3.84 e 0 . 33 0 . 87 1.64 2.30 3.35 u 0 . 28 0 . 79 1.46 2.05 2.93 f 0 . 25 0 . 72 1.31 1.83 2.61 table 2. vdd = 2.5v rise/fall times for specific c load table 3. vdd = 2.8v rise/fall times for specific c load table 4. vdd = 3.0v rise/fall times for specific c load table 5. vdd = 3.3v rise/fall times for specific c load
page 6 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com pin 1 config u ra t i o n op t i o ns (oe, s t , or nc) pi n 1 o f th e htlpo ca n b e pr o g r amme d t o s u pport t h re e m o des : outpu t e n ab le (oe) , st an d b y (s t ) o r n o c o nnect (nc) . output enable (o e ) mode i n th e o e mod e , a p plyi ng lo g i c lo w t o th e o e p i n on ly d isa b les t he o ut p u t driv er an d pu t s i t i n hi - z mod e . th e cor e o f t he dev i c e contin u e s t o o p erat e n orm a ll y . powe r c o nsumptio n is red u c ed d u e t o th e i nactivit y o f th e o u t p ut . wh en th e o e pi n is pu l le d hi g h , th e o ut p u t is typica l l y e na b le d i n < 1s. s t a n d by (s t) mode i n t he s t m od e , a d e v i ce e n t e rs i n to t h e s t a nd by m o de wh en pi n 1 p u lle d l o w . al l i nterna l circu i t s o f th e d evic e ar e turn ed o f f . th e c u rren t i s re d uce d to a s t a ndb y c u rr e n t , typic a ll y i n t he ran ge o f a fe w a. wh en s t i s p ul l e d h igh , th e d e v i c e g o es t h roug h th e ?resum e pr o c e ss , whic h c an t ak e u p t o 5 ms. n o connec t (nc ) mode i n t he n c mo d e, t he d e vic e a l way s op e rate s i n i t s n o rm al mod e a n d o ut p u t t he specifi ed fr e qu e nc y r e gar d les s o f t he lo g i c l eve l o n p i n 1. t ab le 6 b e lo w s u mm a r iz e s t he k e y rel e van t p a rameter s i n t he op e rat i o n o f th e d evic e i n oe , s t , o r n c m o de. out p ut on s t a r tup a nd res u me the htlpo comes with gated output. i t s clock output is accurate to the rated frequency s t ability within the first pulse from initial device st artup or resume from the s t andby mode. in addition, the htlpo has no run t , no glitch output during st artup or resume as shown in the waveform captures in figure 8 and figure 9. programmable drive s trength oe st nc active cu r rent 1 25 mhz (max, 1 . 8 v) 4 ma 4 ma 4 ma o e d i s a bl e curre n t (max . 1 . 8 v ) 3.8 ma n/a n/a s t a n dby cu r rent ( typical 1.8 v ) n/a 0 .6 ua n/a oe e n able time at 1 2 5 mhz (max) 162 n s n/a n/a resum e t i m e fro m s t a n dby (max , a l l fr e quency) n/a 5 ms n/a outp u t driver in oe disabl e / s t a n dby m o de high z p ull - d own n/a table 6. oe vs. st vs. nc figure 8. startup waveform vs. v dd figure 9. startup waveform vs. v dd ( z o om e d - in v i e w of fi g ure 8)
page 7 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com dimensions and patte rns package size C dimen sions (unit:mm) 2.0 x 1.6 x 0.75 mm recommended land pat tern (unit:mm) [6] 1.5 1.2 0.9 0.8 0.750.05 1.60.05 2.00.05 #1 #2 #3 #4 0.68 #2 #1 #4 #3 0.65 0.48 0.93 note: 6. a capacitor value of 0.1 f between v dd and gnd is recommended. package size C dimen sions (unit:mm) 2.5 x 2.0 x 0.75 mm recommended land pat tern (unit:mm) package size C dimen sions (unit:mm) 3.2 x 2.5 x 0.75 mm recommended land pat tern (unit:mm) 1.9 1.5 1.1 1.0 0.750.05 2.00.05 2.50.05 #1 #2 #3 #4 0.75 #2 #1 #4 #3 1.00 0.5 1.1 2.2 1.9 1.4 1.2 0.750.05 2.50.05 3.20.05 #1 #2 #3 #4 0.9 #2 #1 #4 #3 2.1 0.7 0.9
page 8 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com dimensions and patte rns note : 7. a capacitor value of 0.1 f between vdd and gnd is recommended. package size C dimen sions (unit:mm) 5.0 x 3.2 x 0.75 mm recommended land pat tern (unit:mm) [7] 2.54 2.2 1.5 1.6 package size C dimen sions (unit:mm) 7.0 x 5.0 x 0.90 mm recommended land pat tern (unit:mm) 0.750.05 3.20.05 5.00.05 #1 #2 #3 #4 1.15 #2 #1 #4 #3 1.1 0.8 2.39 5.08 3.81 2.2 2.0 0.900.10 5.00.05 7.00.05 #1 #2 #3 #4 1.4 #2 #1 #4 #3 1.1 2.6 5.08 reflow solder profi le
page 9 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com ordering information e xample : htlpo33 - 2520 - e - 25 - y - 75.000mhz - t - s please indicate your required parameters output drive strength s standard (datasheet limits) see tables 1 to 5 for rise/fall times l t a e r u b f oscillator family htlpo supply voltage 18 for 1.8v 25 for 2.5v 28 for 2.8v 3 for 3.0v 33 for 3.3v xx for 2.25v to 3.63v feature pin 1 e for output enable s for standby n for no connect frequency 1.000000 to 110.000000 mh z package size 2016 for 2.0 x 1.6 mm 2520 for 2.5 x 2.0 mm 3225 for 3.2 x 2.5 mm 5032 for 5.0 x 3.2 mm 7050 for 7.0 x 5.0 mm frequency stability 20 for 20 ppm 25 for 25 ppm 30 for 30 ppm 50 for 50 ppm htlpo 33 - 2520 - e - 25 - y - 75.000mhz - t - s packing method b bulks or tubes t t ape & reel temperature range y for - 40 +105c z for - 40 +125c samples are available within a short delivery period!
page 10 of 10 i spec 01 i rev.00 i november 2014 crystals ? oscillators ? ceramic resonators ? ceramic filters ? saw components petermann - technik gmbh lechwiesenstr. 13 ? d - 86899 ? landsberg am lech tel: +49/8191/305395 ? fax: +49/8191/305397 info@petermann - technik.com ? www.petermann - technik.com premium quality by petermann - technik our company is certi fied according to is o 9001:2008 in o c- tober 2013 by the dm sz certifikation gmbh. this is for you to e nsure that the principles of quality management are fully implemented in our quality ma- nagement system and quality control meth ods also do- minate our quality standards. ? petermann - technik gmbh 2014. the information contained herein is subject to change at any time without notice. petermann - techn ik owns all rights, title and interest to the intellectual property related to petermann - technik's products, including any software, fir mware, copyright, pa- tent, or trademark. the sale of petermann - technik products does not convey or imply any license under patent or other rights. pe termann - technik retains the copyright and trademark rights in all documents, catalogs and plans supplied pursuant to or ancillary to the sale of products or services by petermann - technik. unless otherwise agreed to in writing by petermann - technik, any reproduction, modification, trans lation, com- pilation, or representation of this material shall be strictly prohibited.
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