1 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 description � integrated synthesizer plus fanout buffers, clock drivers, and translator in a single 64-pin package � 3.3v 10% power supply � low jitter: <50ps cycle-to-cycle � low pin-to-pin skew: <50ps � 33mhz to 500mhz output frequency range � direct interface to crystal: 14mhz to 18mhz � lvpecl/hstl outputs � ttl/cmos compatible control logic � 3 independently programmable output frequency banks: � 9 differential output pairs @bankb (hstl) � 2 differential output pairs @banka (lvpecl) � 2 differential output pairs @bankc (lvpecl) � extvco input allows synthesizer and crystal interface to be bypassed � available in 64-pin epad-tqfp features 3.3v, precision, 33mhz to 500mhz programmable lvpecl and hstl bus clock synthesizer precision edge � sy89531l applications � servers � workstations � parallel processor-based systems � other high-performance computing � communications rev.: c amendment: /0 issue date: january 2008 the sy89531l programmable clock synthesizer/driver is part of a 3.3v, high-frequency, precision pll-based clock synthesizer family optimized for multi-frequency, multi- processor server, enterprise networking and other computing applications that require the highest precision and integration. the device integrates the following blocks into a single monolithic ic: � pll (phase-lock-loop)-based synthesizer � fanout buffers � clock generator (dividers) � logic translation (lvpecl, hstl) this level of integration minimizes the additive jitter and part-to-part skew associated with the discrete alternative, resulting in superior system-level timing as well as reduced board space and power. for applications that must interface to a reference clock, see the sy89536l. datasheets and support documentation can be found on micrel? web site at: www.micrel.com. product selection guide input output device crystal r eference banka bankb bankc sy89531l x lvpecl hstl lvpecl sy89532l* x lvpecl lvpecl lvpecl sy89533l* x lvpecl lvds lvpecl sy89534l* x lvpecl lvpecl lvpecl sy89535l* x lvpecl lvds lvpecl sy89536l* x lvpecl hstl lvpecl *refer to individual data sheet for details. precision edge � precision edge is a registered trademark of micrel, inc.
2 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 vcc_logic qb0 vccob /qa1 qa1 /qa0 qa0 vccoa fsel_a2 fsel_a1 fsel_a0 out_sync vcc_logic vcca gnd nc nc nc nc vco_sel /extvco extvco loop_ref loop_filter gnd xtal2 xtal1 vbb_ref m(3) m(2) m(1) m(0) /qb0 qb1 /qb1 qb2 /qb2 qb3 /qb3 qb4 /qb4 qb5 /qb5 qb6 /qb6 qb7 /qb7 qb8 64 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 qc0 /qb8 vccob vccob gnd fsel_b0 fsel_b1 fsel_b2 gnd fsel_c0 fsel_c1 fsel_c2 vccoc /qc0 qc1 /qc1 64-pin epad-tqfp (h64-1) package/ordering information ordering information (1) package operating package lead part number type range marking finish sy89531lhc h64-1 commercial sy89531lhc sn-pb sy89531lhctr (2) h64-1 commercial sy89531lhc sn-pb SY89531LHZ (3) h64-1 commercial SY89531LHZ with matte-sn pb-free bar-line indicator pb-free SY89531LHZtr (2, 3) h64-1 commercial SY89531LHZ with matte-sn pb-free bar-line indicator pb-free notes: 1. contact factory for die availability. dice are guaranteed at t a = 25 c, dc electricals only. 2. tape and reel. 3. pb-free package is recommended for new designs.
3 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 pin description power pin number pin name pin function 60, 61 v cc_logic power for core logic: connect to 3.3v supply. 3.3v power pins are not internally connected on the die, and must be connected together on the pcb. 62 v cca power for pll: connect to � quiet � 3.3v supply. 3.3v power pins are not internally connected on the die, and must be connected together on the pcb. 55 v cco a power for output drivers: connect all v cco a and v cco c pins to 3.3v supply and v cco b 30, 31, 50 v cco b pins to 1.8v supply. 21 v cco c 9, 25, 63, 29 gnd ground: exposed pad must be soldered to a ground plane. (exposed pad) configuration pin number pin name pin function 4 vco_sel lvttl/cmos compatible input: selects between internal or external vco. for external vco, leave floating. default condition is logic high. internal 25k ? pull-up. when tied low, internal vco is selected. 7 loop ref analog input/output: provides the reference voltage for pll loop filter. 8 loop filter analog input/output: provides the loop filter for pll. see � external loop filter considerations � for loop filter values. 13,14,15,16 m (3:0) lvttl/cmos compatible input: used to change the pll feedback divider. internal 25k ? pull-up. m0 = lsb. default is logic high. see � feedback divide select � table. 22, 23, 24 fsel_c (2:0) lvttl/cmos compatible input: bank c post divide select. internal 25k ? pull-up. default is logic high. see � post-divide frequency select � table. fsel_c0 = lsb. 26, 27, 28 fsel_b (2:0) lvttl/cmos compatible input: bank b post divide select. internal 25k ? pull-up. default is logic high. see � post-divide frequency select � table. fsel_b0 = lsb. 56, 57, 58 fsel_a (2:0) lvttl/cmos compatible input: bank a post divide select. internal 25k ? pull-up. default is logic high. see � post-divide frequency select � table. fsel_a0 = lsb. 59 out_sync banks a, b, c output synchronous control: (lvttl/cmos compatible). internal 25k ? pull-up. after any bank has been programmed, toggle with a high-low-high pulse to resynchronize all output banks. input/output pin number pin name pin function 1, 2, 3 nc no connect: leave floating. 10, 11 xtal2, xtal1 crystal input. directly connect a series resonant crystal across inputs. 12 vbb_ref reference output voltage. used for single-ended input. maximum sink/source current = 0.5ma. 5, 6 /ext_vco, differential � any in � compatible input pair. allows for external vco connection. the � any ext_vco in � input structure accepts many popular logic types. see � input interface for extvco pins � section for interface diagrams. can leave unconnected if using internal vco. 51, 52, 53, 54 qa1 to qa0 bank a 100k lvpecl output drivers: output frequency is controlled by fsel_a (0:2). terminate outputs with 50 ? to v cc � 2v. see � output termination recommendations � section. 32 � 49 qb8 to qb0 bank b output drivers: differential hstl outputs. see � output termination recommendations � section. output frequency is controlled by fsel_b (0:2). 17, 18, 19, 20 qc1 to qc0 bank c 100k lvpecl output drivers: output frequency is controlled by fsel_c (0:2). terminate outputs with 50 ? to v cc � 2v. see � output termination recommendations � section. 64 nc no connect: leave floating.
4 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 absolute maximum ratings (note 1) supply voltage (v in ) ................................... � 0.5v to +4.0v v cc pin potential to ground pin (all v cc ).. � 0.5v to +4.0v input voltage (except xtal 1,2 pins) (v in ) ... � 0.5v to v cci xtal 1, 2 input voltage (v xtal 1,2 ) ...... (v cc � 1.9v) to v cc dc output current (i out ) � lvpecl, hstl outputs ..................................... � 50ma lead temperature (soldering, 20 sec.) ..................... 260 c storage temperature (t s ) ....................... � 65 c to +150 c operating ratings (note 2) supply voltage v cco a and v cco c ...................................... 3.0v to 3.6v v cco b ......................................................... 1.6v to 2.0v ambient temperature (t a ) ............................. 0 c to +85 c package thermal resistance (junction-to-ambient) with die attach soldered to gnd: tqfp ( ja ) still-air .............................................. 23 c/w tqfp ( ja ) 200lfpm ............................................ 18 c/w tqfp ( ja ) 500lfpm ............................................ 15 c/w with die attach not soldered to gnd, note 3 tqfp ( ja ) still-air .............................................. 44 c/w tqfp ( ja ) 200lfpm ............................................ 36 c/w tqfp ( ja ) 500lfpm ............................................ 30 c/w package thermal resistance (junction-to-case) tqfp ( jc ) ......................................................... 4.3 c/w power supply symbol parameter condition min typ max units v cca pll and logic supply voltage note 4 3.0 3.3 3.6 v v cc_logic v cco a/c bank a and c v cc output 3.0 3.3 3.6 v v cco b bank b v cc output lvpecl/hstl 1.6 1.8 2.0 v i cc total supply current note 5 � 230 295 ma dc electrical characteristics note 1. permanent device damage may occur if absolute maximum ratings are exceeded. this is a stress rating only and functional operati on is not implied at conditions other than those detailed in the operational sections of this data sheet. exposure to absolute maximum ratlng con ditions for extended periods may affect device reliability. note 2. the data sheet limits are not guaranteed if the device is operated beyond the operating ratings. note 3. it is recommended that the user always solder the exposed die pad to a ground plane for enhanced heat dissipation. note 4. v cca , v cc_logic , v cco a/c are not internally connected together inside the device. they must be connected together on the pcb. v cco b is a separate supply. note 5. no load. outputs floating, banks a, b, and c enabled.
5 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 dc electrical characteristics lvcmos/lvttl input control logic (v cca , v cc_logic , v cco a/c = +3.3v 10%) symbol parameter condition min typ max units v ih input high voltage 2.0 v v il input low voltage 0.8 v i ih input high current 150 a i il input low current � 300 a extvco (pins 5, 6) input (all v cc pins except v cco b = +3.3v 10%, v cco b = +1.8v 10%) symbol parameter condition min typ max units v id differential input voltage 100 mv v ih input high voltage v cc +0.3 v v il input low voltage � 0.3 � � v 100k lvpecl output (all v cc pins except v cco b = +3.3v 10%, v cco b = +1.8v 10%) (note 6) symbol parameter condition min typ max units v oh output high voltage v cc � 1.145 v cc � 1.020 v cc � 0.895 v v ol output low voltage v cc � 1.945 v cc � 1.820 v cc � 1.695 v v bb output reference voltage v cc � 1.325 v cc � 1.425 v cc � 1.525 v v out output voltage swing � 800 � mv hstl output (bank b qb0:8) (all v cc pins except v cco b = +3.3v 10%, v cco b = +1.8v 10%) (note 7) symbol parameter condition min typ max units v out output voltage swing � 800 � mv v oh output high voltage 1.0 � 1.2 v v ol output low voltage 0.2 � 0.4 v note 6. all lvpecl outputs loaded with 50 ? to v cc � 2v. note 7. all hstl outputs loaded with 50 ? to gnd.
6 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 v cc_logic = v cca = v cco a/c = +3.3v 10%, v cco b = +1.8v 10% symbol parameter condition min typ max units f in xtal input frequency range note 8 14 � 18 mhz f out output frequency range w/internal vco 33.33 � 500 mhz w/external vco 622.08 mhz t vco internal vco frequency range 600 � 1000 mhz external vco frequency 1250 mhz t skew within device skew 50 ps note 9 within-bank pecl 50 ps within-bank hstl 75 ps between banks 150 ps part-to-part skew note 10 200 ps t lock maximum pll lock time 10 ms t jitter cycle-to-cycle jitter (pk-to-pk) note 11 � 25 � ps period jitter (rms) note 12 50 ps t pw (min) minimum pulse width 50 ns target pll loop bandwidth feedback divider ratio: 72 note 13 � 1.0 � mhz feedback divider ratio: 34 note 13 � 2.0 � mhz t dc f out duty cycle 45 50 55 % t r , t f output rise/fall time (20% to 80%)lvpecl_out � 250 450 ps hstl_out 100 � 450 ps t output_reset note 14 10 ns t hold_fsel 5 ns t setup_fsel 5 ns t output_sync 1 vco clock cycle fsel-to-valid output transition time 1 s t setup_out_sync 500 ps note 8 . fundamental mode crystal. note 9. the within-device skew is defined as the worst case difference between any two similar delay paths within a single device opera ting at the same voltage and temperature. note 10. the part-to-part skew is defined as the absolute worst case difference between any two delay paths on any two devices operating at the same voltage and temperature. note 11 . cycle-to-cycle jitter definition: the variation in period between adjacent cycles over a random sample of adjacent cycle pairs . t jitter_cc =t n � t n+1 where t is the time between rising edges of the output signal. note 12. period jitter definition: for a specified amount of time (i.e., 1ms), there are n periods of a signal, and t n is defined as the average period of that signal. period jitter is defined as the variation in the period of the output signal for corresponding edges relative to t n . note 13. using recommended loop filter components. see � functional description, external loop filter considerations. � note 14. see � timing diagrams. � ac electrical characteristics
7 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 timing diagrams conditions: internal vco, unless otherwise stated. t hold_fsel vco fsel fout out_sync t output_sync 010 time 001 t setup_fsel t output_reset frequency programming (internal vco clock) vco (ext.) fsel fout out_sync t output_sync 010 time 001 t setup_ out_sync t output_reset frequency programming (external vco clock) vco fsel fout out_sync f sel to valid output transition time 010 time 001 output frequency update to valid output
8 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 functional block diagram oscillator 4 5 6 7 8 v cc � 1.425v reference or bandgap reference charge pump phase detector 12 13 14 62 61 64 63 23 1 60 58 57 56 54 53 52 51 3-bit divider a 2, 4, 6, 8, 10, 12,18 extvco vco_sel /extvco loop ref loop filter vbb_ref (msb) m3 3 2x 9x 50 49 48 47 46 45 44 43 42 41 40 39 38 37 36 35 34 33 32 29 28 27 26 25 24 23 22 21 20 19 18 3 vco (600mhz to 1000mhz) /qa1 v cco b qb0 /qb0 qb1 /qb1 qb2 /qb2 qb3 /qb3 qb4 /qb4 qb5 /qb5 qb6 /qb6 qb7 /qb7 qb8 /qb8 59 31 30 v cco b v cco b qa1 /qa0 qa0 55 v cco a a en b en 3-bit divider b 2, 4, 6, 8, 10, 12,18 3-bit divider c 2, 4, 6, 8, 10, 12,18 c en fsel_a2 fsel_a1 fsel_a0 (lsb) out_sync m-divide 34, 36, 38, 40, 42 44, 48, 50, 52, 54 56, 60, 62, 66, 70, 72 v cc _logic v cc _logic v cca gnd nc nc nc nc 9 gnd 10 xtal2 11 xtal1 buf mux 1 clock gnd fsel_b0 (lsb) fsel_b1 fsel_b2 gnd fsel_c0 (lsb) fsel_c1 fsel_c2 17 v cco c qc0 /qc0 qc1 /qc1 3 buf 5 0 = internal vco enabled 1 = internal vco disabled (default) vco select 14mhz to 18mhz 14mhz to 18mhz 600mhz to 1000mhz 2x m2 15 16 m1 (lsb) m0
9 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 functional description at the core of the sy89531l clock synthesizer is a precision pll driven by 14mhz to 18mhz series resonant crystal. for users who wish to supply a ttl or lvpecl clock input, please use the sy89536l. the pll output is sent to three banks of outputs. each bank has its own programmable frequency divider, and the design is optimized to provide very low skew between banks, and very low jitter. pll programming and operation important: if the internal vco will be used, vco_sel must be tied low, and extvco pins can be left unconnected. the internal vco range is 600mhz to 1000mhz, and the feedback ratio is selectable via the msel divider control (m3:0 pins). the vco_sel pin must be tied low. the feedback ratio can be changed without powering the chip down. the pll output is fed to three banks of outputs: bank a, bank b, and bank c. banks a and c each have two differential lvpecl output pairs. bank b has nine differential hstl output pairs. each bank has a separate frequency divider circuit that can be reprogrammed on the fly. the fsel_x0:2 (where x is a, b, or c) pins control the divider value. the fsel divider can be programmed in ratios from 2 to 18, and the outputs of banks a, b, and c can be synchronized after programming by pulsing the out_sync pin high-low- high. setting a value of 000 for fsel is an output disable forcing the q outputs to be low and the /q outputs to be high. doing so will decrease power consumption by approximately 5ma per bank. to determine the correct settings for the sy89531l follow these steps: 1. refer to the � suggested selections for specific customer applications � section for common applications, as well as the formula used to compute the output frequency. 2. determine the desired output frequency, such as 66mhz. 3. choose a crystal frequency between 14mhz and 18mhz. in this example, we choose 18mhz for the crystal frequency. this results in an input/output ratio of 66/18. 4. refer to the � feedback divide select � table and the � post-divide frequency select � table to find values for msel and fsel such that msel/fsel equals the same 66/18 ratio. in this example, values of msel=44 and fsel=12 work. 5. make sure that xtal (the crystal frequency) multiplied by msel is between 600mhz and 1000mhz. the user may need to experiment with different crystal frequencies to satisfy these requirements. extvco input interface the flexible extvco inputs are designed to accept any differential or single-ended input signal within 300mv above v cc and 300mv below ground. do not leave unused extvco inputs floating. tie either the true or complement inputs to ground, but not both. a logic zero is achieved by connecting the complement input to ground with the true input floating. for a ttl input, see � input interface for extvco pins � section, figures 5a through 5h. input levels lvds, cml and hstl differential signals may be connected directly to the extvco inputs. depending on the actual worst case voltage seen, the minimum input voltage swing varies. r2 990 ? r2 990 ? r1 825 ? r1 825 ? gnd extvco v cc /extvco figure 1. simplified input structure
10 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 crystal input and oscillator interface the sy89531l features a fully integrated on-board oscillator to minimize system implementation costs. the oscillator is a series resonant, multivibrator type design, and thus, a series-resonant crystal is preferred, but not required. a parallel-resonant crystal can be used with the sy89531l with only a minor error in the desired frequency. a parallel- resonant mode crystal used in a series resonant circuit will exhibit a frequency of oscillation a few hundred ppm lower than specified; a few hundred ppm translates to khz inaccuracies. in a general computer application this level of inaccuracy is immaterial. as the oscillator is somewhat sensitive to loading on its inputs, the user is advised to mount the crystal as close to the sy89531l as possible to avoid any board level parasitics. in addition, trace lengths should be matched. figure 2 shows how to interface with a crystal. table 1 illustrates the crystal specifications. certain crystals may require a 10pf capacitor across xtal1 and xtal2 for proper operation. this is normally not required, but it is recommended that provisions be made for it. sy89531l xtal2 (pin 26, soic) xtal1 (pin 25, soic) xtal 16.666mhz quartz crystal selection: (1) raltron series resonant: as-16.666-s-smd-t-mi (2) raltron parallel resonant: as-16.666-18-smd-t-mi optional figure 2. crystal interface external loop filter considerations the sy89531l features an external pll loop filter that allows the user to tailor the pll � s behavior to their application and operating environment. we recommend using ceramic capacitors with npo or x7r dielectric, as they have very- low effective series resistance. for applications that require ultra-low cycle-to-cycle jitter, use the components shown in figure 3. the pll loop bandwidth is a function of feedback divider ratio, and the external loop filter allows the user to compensate. for instance, the pll � s loop bandwidth can be decreased by using a smaller resistor in the loop filter. this results in less noise from the pll input, but potentially more noise from the vco. refer to � ac electrical characteristics � for target pll loop bandwidth. the designer should take care to keep the loop filter components on the same side of the board and as close as possible to the sy89531l � s loop_ref and loop_filter pins. to insure minimal noise pick up on the loop filter, it is desirable to cut away the ground plane directly underneath the loop filter component pads and traces. however, the benefit may not be significant in all applications and one must be careful to not alter the characteristic impedance of nearby traces. 470pf loop filter loop reference 330 ? 0.2 f figure 3. external loop filter connection table 1. quartz crystal oscillator specifications output frequency: 14mhz-18mhz mode of oscillation: fundamental min typ max unit frequency tolerance @25 c � 30 50 ppm frequency stability over 0 c to 70 c � 50 100 ppm operating temperature range � 20 � +70 c storage temperature range � 55 � +125 c aging (per yr/first 3 yrs) 5 ppm load capacitance � 18 (or series) � pf equivalent series resistance (esr) 50 ? drive level � 100 � w
11 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 power supply filtering techniques as with any high-speed integrated circuit, power supply filtering is very important. at a minimum, v cc a, v cc _logic, and all v cco pins should be individually connected using a via to the power supply plane, and separate bypass capacitors should be used for each pin. to achieve optimal jitter performance, each power supply pin should use separate instances of the circuit shown in figure 4. *for v cc_ analog,v cc_ttl, v cc1, use ferrite bead = 200ma, 0.45 ? dc, murata p/n blm21a1025 *for v cc_out use ferrite bead = 3a, 0.025 ? dc, murata, p/n blm31p005 *component size: 0805 1 f 22 f 0.01 f ferrite bead* � power supply � side � device � side v cc pins figure 4. power supply filtering output logic characteristics see � output termination recommendations � for illustrations. in cases where single-ended output is desired, the designer should terminate the unused complimentary output in the same manner as the normal output that is begin used. unused output pairs can be left floating. unused output banks can be switched off by tying the appropriate fsel pins to ground. unused output pairs that are in a bank that is disabled can be left floating, regardless of output driver type. lvpecl operation: � typical voltage swing is 700mv pp to 800mv pp into 50 ? . � common mode voltage is v cc � 1.3v, typical. � 100 ? termination across the output pair is not recommended for lvpecl. hstl operation (bank b): � typical voltage swing is 250mv pp to 450mv pp into effective 50 ? . thermal considerations this part has an exposed die pad for enhanced heat dissipation. we strongly recommend soldering the exposed pad to a ground plane. where this is not possible, we recommend maintaining at least 500lfpm air flow. for additional information on exposed-pad characteristics and implementation details, see amkor technology � s write- up at www.amkor.com. fsel_a2 (1) (msb) fsel_a1 (1) fsel_a0 (1) (lsb) output divider 0 0 0 output disable function, all outputs: q = low, /q = high 0 0 1 vco 2 0 1 0 vco 4 0 1 1 vco 6 1 0 0 vco 8 1 0 1 vco 10 1 1 0 vco 12 1 1 1 vco 18 post-divide frequency select table (fsel) note 1. same dividers apply to fsel_b (0:2) and fsel_c (0:2).
12 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 rate fsel msel xtal protocol (mhz) (post divider) (feedback div.) (mhz) fout pci 33 18 36 16.67 33 fast ethernet 100 6 40 15 100 1/8 fc 133 6 52 15.36 133 escon 200 4 50 16 200 suggested selections for specific customer applications (notes 1, 2) note 1. 600mhz < (xtal x msel) < 1000mhz. note 2. where two settings provide the user with the identical desired frequency, the setting with the higher input reference frequency (and lower feedback divider) will usually have lower output jitter. however, the reference input frequency, as well as the vco frequency, must be kept within their respective ranges. fout xtal msel fsel = () m3 m2 m1 m0 vco frequency (1) 0000 ref 34 0001 ref 36 0010 ref 38 0011 ref 40 0100 ref 42 0101 ref 44 0110 ref 48 0111 ref 50 1000 ref 52 1001 ref 54 1010 ref 56 1011 ref 60 1100 ref 62 1101 ref 66 1110 ref 70 1111 ref 72 note 1. ref = crystal frequency. feedback divide select table (msel)
13 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 input interface for extvco pins extvco /extvco sy89531l ttl lvttl 1% v cc(driver) v cc v cc(driver) figure 5a. 3.3v � ttl � cml extvco /extvco v cc(driver) v cc v cc(driver) 102 ? 1% sy89531l figure 5b. cml dc-coupled extvco /extvco sy89531l 2.5v lvttl 1% 2.3v to 2.7v 3.0v to 3.6v figure 5c. 2.5v � lvttl � extvco /extvco 50 ? 1% 50 ? 1% v cc(driver) v cc v cc(driver) sy89531l v cc � 2v pecl figure 5d. 3.3v lvpecl dc-coupled hstl extvco /extvco sy89531l v cc 50 ? 50 ? figure 5e. hstl extvco /extvco 3.92k ? 1% 3.92k ? 1% 102 ? 1% v cc(driver) v cc sy89531l cml figure 5f. cml ac-coupled (short trace lengths)
14 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 cml extvco /extvco 130 ? 1% 130 ? 1% v cc(driver) v cc sy89531l 82 ? 1% 82 ? 1% v cc figure 5g. cml ac-coupled (long trace lengths) lvds extvco /extvco v cc 100 ? 1% sy89531l figure 5h. lvds
15 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 r2 82 ? r2 82 ? z o = 50 ? z o = 50 ? +3.3v +3.3v v t = v cc � 2v r1 130 ? r1 130 ? +3.3v � source destination � figure 6. pecl parallel termination thevenin equivalent (note 1) z o = 50 ? z o = 50 ? 50 ? 50 ? 50 ? +3.3v +3.3v � source destination � r b c1 (optional) 0.01 f figure 7. lvpecl three-resistor � y-termination � (notes 1, 2, 3) z o = 50 ? z o = 50 ? +3.3v +3.3v source destination 50 ? 50 ? figure 8. hstl differential termination (note 1) note 1. place termination resistors as close to destination inputs as possible. note 2. pecl y-termination is a power-saving alternative to thevenin termination. note 3. r b resistor sets the dc bias voltage, equal to v t . for +3.3v systems r b = 46 ? to 50 ? . output termination recommendations
16 precision edge � sy89531l micrel, inc. m9999-010808 hbwhelp@micrel.com or (408) 955-1690 64-pin epad-tqfp (die up) (h64-1) rev. 02 +0.05 � 0.05 +0.002 � 0.002 +0.006 � 0.006 +0.012 � 0.012 +0.002 � 0.002 +0.15 � 0.15 +0.03 � 0.03 +0.05 � 0.05 +0.012 � 0.012 +0.05 � 0.05 package ep- exposed pad die compside island heat dissipation heavy copper plane heavy copper plane v ee v ee heat dissipation pcb thermal consideration for 64-pin epad-tqfp package package notes: note 1. package meets level 2 moisture sensitivity classification, and is shipped in dry-pack form. note 2. exposed pads must be soldered to a ground for proper thermal management. micrel, inc. 2180 fortune drive san jose, ca 95131 usa tel + 1 (408) 944-0800 fax + 1 (408) 474-1000 web http://www.micrel.com the information furnished by micrel in this datasheet is believed to be accurate and reliable. however, no responsibility is as sumed by micrel for its use. micrel reserves the right to change circuitry and specifications at any time without notification to the customer. micrel products are not designed or authorized for use as components in life support appliances, devices or systems where malfu nction of a product can reasonably be expected to result in personal injury. life support devices or systems are devices or systems that (a) are intend ed for surgical implant into the body or (b) support or sustain life, and whose failure to perform can be reasonably expected to result in a significant inj ury to the user. a purchaser � s use or sale of micrel products for use in life support appliances, devices or systems is at purchaser � s own risk and purchaser agrees to fully indemnify micrel for any damages resulting from such use or sale. ? 2005 micrel, incorporated.
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