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electrical specifications subject to change LTM2881 1 2881p typical application description complete isolated rs485/rs422 module transceiver + power the ltm ? 2881 is a complete galvanically isolated full- duplex rs485/rs422 module ? transceiver. no external components are required. a single supply powers both sides of the interface through an integrated, isolated, low noise, ef? cient 5v output dc/dc converter. coupled inductors and an isolation power transformer provide 2500v rms of isolation between the line transceiver and the logic interface. this device is ideal for systems where the ground loop is broken allowing for large common mode voltage variation. uninterrupted communication is guaranteed for common mode transients greater than 30kv/s. maximum data rates are 20mbps or 250kbps in slew limited mode. transmit data, di and receive data, ro, implemented with event driven low jitter processing. the receiver has a one-eighth unit load supporting up to 256 nodes per bus. a logic supply pin allows easy interfacing with different logic levels from 1.62v to 5.5v, independent of the main supply. enhanced esd protection allows this part to withstand up to 15kv (human body model) on the transceiver interface pins to isolated supplies and 10kv through the isolation barrier to logic supplies without latch-up or damage. isolated half-duplex rs485 module transceiver features applications n isolator module technology n isolated rs485/rs422 transceiver: 2500v rms n integrated isolated dc/dc converter: 1w, 62% ef? ciency n no external components required n 20mbps or low emi 250kbps data rate n high esd: 15kv hbm on transceiver interface n high common mode transient immunity: 30kv/s n integrated selectable 120 termination n 3.3v (LTM2881-3) or 5.0v (LTM2881-5) operation n 1.62v to 5.5v logic supply pin for flexible digital interface n common mode working voltage: 560v peak n high input impedance failsafe rs485 receiver n current limited drivers and thermal shutdown n compatible with tia/eia-485-a speci? cation n high impedance output during internal fault condition n low current shutdown mode (< 5a) n general purpose cmos isolated channel n small, low pro? le (15mm 11.25mm 2.8mm) surface mount lga and bga packages n isolated rs485/rs422 interface n industrial networks n breaking rs485 ground loops 2881 ta01 twisted-pair cable a ro v l te re de di gnd gnd2 v cc 3.3v LTM2881 b y z pwr galvanic isolation LTM2881 operating through 35kv/s cm transient l , lt, ltc, ltm, linear technology, module and the linear logo are registered trademarks of linear technology corporation. all other trademarks are the property of their respective owners. 2881 ta01a 500v/div 50ns/div 1v/div 1v/div di ro multiple sweeps of common mode transients
LTM2881 2 2881p pin configuration absolute maximum ratings v cc to gnd .................................................. ? 0.3v to 6v v cc2 to gnd2 ............................................... ? 0.3v to 6v v l to gnd .................................................... ? 0.3v to 6v interface voltages (a, b, y, z) to gnd2 ........................ v cc2 ?15v to 15v signal voltages on, ro, di, de, re, te, d out to gnd ......................... ? 0.3v to v l +0.3v signal voltages slo, d in to gnd2 ....................................? 0.3v to v cc2 +0.3v operating temperature range LTM2881c................................................ 0c to 70c LTM2881i .............................................? 40c to 85c storage temperature range ...................? 55c to 125c peak re? ow temperature (soldering, 10 sec) ...... 260c (note 1) bga/lga package 32-pin (15mm s 11.25mm s 2.8mm) top view slo d in ro v l on re dedited out 1 a b c d e f g h j k l 2345678 v cc2 z gnd2 gnd ba y v cc t jmax = 125c,
LTM2881 3 2881p electrical characteristics symbol parameter conditions min typ max units power supply v cc v cc supply voltage LTM2881-3 LTM2881-5 l l 3.0 4.5 3.3 5.0 3.6 5.5 v v v l v l supply voltage l 1.62 5.5 v i ccpoff v cc supply current in off mode on = 0v l 05 a i ccs v cc supply current in on mode LTM2881-3 de = 0v, re = v l , no load LTM2881-5 de = 0v, re = v l , no load l l 20 15 25 19 ma ma v cc2 regulated v cc2 output voltage, loaded ltm 2881-3 de = 0v, re = v l , i load = 100ma LTM2881-5 de = 0v, re = v l , i load = 180ma 4.5 4.5 5.0 5.0 v v v cc2noload regulated v cc2 output voltage, no load de = 0v, re = v l , no load l 4.8 5.0 5.2 v ef? ciency i cc2 = 100ma (note 2) 50 % i cc2s v cc2 short-circuit current de = 0v, re = v l , v cc2 = 0v l 250 ma driver |v od | differential driver output voltage r = (figure 1) r = 27 (rs485) (figure 1) r = 50 (rs422) (figure 1) l l l 1.5 2 v cc2 v cc2 v cc2 v v v |v od | difference in magnitude of driver differential output voltage for complementary output states r = 27 or r = 50 (figure 1) l 0.2 v v oc driver common mode output voltage r = 27 or r = 50 (figure 1) l 3v |v oc | difference in magnitude of driver common mode output voltage for complementary output states r = 27 or r = 50 (figure 1) l 0.2 v i ozd driver three-state (high impedance) output current on y and z de = 0v, (y or z) = C7v, +12v l 10 a i osd maximum driver short-circuit current C 7v (y or z) 12v (figure 2) l C 250 250 ma receiver r in receiver input resistance re = 0v or v l , v in = C7v, C3v, 3v, 7v, 12v (figure 3) l 96 125 k r te receiver termination resistance enabled te = v l , v ab = 2v, v b = C 7v, 0v, 10v (figure 8) l 108 120 156 i in receiver input current (a, b) on = 0v v cc2 = 0v or 5v, v in = 12v (figure 3) l 125 a on = 0v v cc2 = 0v or 5v, v in = C7v (figure 3) l C100 a v th receiver differential input threshold voltage (a-b) C7v b 12v l C0.2 0.2 v v th receiver input failsafe hysteresis b = 0v l 25 mv receiver input failsafe threshold b = 0v l C0.2 C0.01 v logic v il logic input low voltage 1.62v v l 5.5v l 0.4 v v ih logic input high voltage d in slo di, te, de, on, re: v l 2.35v 1.62v v l < 2.35v l l l l 0.67?v cc2 2 0.67?v l 0.75?v l v v v v the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. LTM2881-3 v cc = 3.3v, LTM2881-5 v cc = 5.0v, v l = 3.3v, gnd = gnd2 = 0v, on = v l unless otherwise noted.
LTM2881 4 2881p symbol parameter conditions min typ max units i inl logic input current l 01 a v hys logic input hysteresis (note 2) 150 mv v oh output high voltage output high, i load = C4ma (sourcing), 5.5v v l 3v output high, i load = C1ma (sourcing), 1.62v v l < 3v l l v l C0.4 v l C0.4 v v v ol output low voltage output low, i lo ad = 4ma (sinking), 5.5v v l 3v output high, i load = 1ma (sinking), 1.62v v l < 3v l l 0.4 0.4 v v i ozr three-state (high impedance) output current on ro re = v l , 0v ro v l l 1 a i osr short-circuit current 0v (ro or d out ) v l l 85 ma electrical characteristics the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. LTM2881-3 v cc = 3.3v, LTM2881-5 v cc = 5.0v, v l = 3.3v, gnd = gnd2 = 0v, on = v l unless otherwise noted. switching characteristics the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. LTM2881-3 v cc = 3.3v, LTM2881-5 v cc = 5.0v, v l = 3.3v, gnd = gnd2 = 0v, on = v l unless otherwise noted. symbol parameter conditions min typ max units driver slo = v cc2 f max maximum data rate (note 3) 20 mbps t plhd t phld driver input to output r diff = 54, c l = 100pf (figure 4) l 60 85 ns t pd driver input to output difference |t plhd C t phld | r diff = 54, c l = 100pf (figure 4) l 18 ns t skewd driver output y to output z r diff = 54, c l = 100pf (figure 4) l 18 ns t rd t fd driver rise or fall time r diff = 54, c l = 100pf (figure 4) l 4 12.5 ns t zld , t zhd , t lzd , t hzd driver output enable or disable time r l = 500, c l = 50pf (figure 5) l 170 ns driver slo = gnd2 f max maximum data rate (note 3) 250 kbps t plhd t phld driver input to output r diff = 54, c l = 100pf (figure 4) l 1 1.55 s t pd driver input to output difference |t plhd C t phld | r diff = 54, c l = 100pf (figure 4) l 50 500 ns t skewd driver output y to output z r diff = 54, c l = 100pf (figure 4) l 200 500 ns t rd t fd driver rise or fall time r diff = 54, c l = 100pf (figure 4) l 0.9 1.5 s t zld , t zhd , t lzd , t hzd driver output enable or disable time r l = 500, c l = 50pf (figure 5) l 400 ns
LTM2881 5 2881p isolation characteristics t a = 25c, LTM2881-3 v cc = 3.3v, LTM2881-5 v cc = 5.0v, v l = 3.3v unless otherwise noted. symbol parameter conditions min typ max units v iso rated dielectric insulation voltage 1 minute (derived from 1 second test) 2500 v rms 1 second 4400 v dc common mode transient immunity (note 2) 30 kv/s v iorm maximum working insulation voltage (note 2) 560 v peak partial discharge v pr = 1050 v peak (note 2) <5 pc input to output resistance (note 2) >10 9 input to output capacitance (note 2) 6 pf creepage distance (note 2) 9.48 mm note 1: stresses beyond those listed under absolute maximum ratings may cause permanent damage to the device. exposure to any absolute maximum rating condition for extended periods may affect device reliability and lifetime. note 2: guaranteed by design and not subject to production test. note 3: maximum data rate is guaranteed by other measured parameters and is not tested directly. note 4: this module transceiver includes over temperature protection that is intended to protect the device during momentary overload conditions. junction temperature will exceed 125c when over temperature protection is active. continuous operation above speci? ed maximum operating junction temperature may result in device degradation or failure. symbol parameter conditions min typ max units receiver t plhr t phlr receiver input to output c l = 15pf, v cm = 2.5v, |v ab | = 1.4v, t r and t f < 4ns, (figure 6) l 100 140 ns t skewr differential receiver skew |t plhr - t phlr | c l = 15pf (figure 6) l 18 ns t rr t fr receiver output rise or fall time c l = 15pf (figure 6) l 3 12.5 ns t zlr , t zhr , t lzr , t hzr receiver output enable time r l =1k, c l = 15pf (figure 7) l 50 ns t rten , t rtz termination enable or disable time re = 0v, de = 0v, v ab = 2v, v b = 0v (figure 8) l 100 s generic logic input t plhl1 t phll1 d in to d out input to output c l = 15pf, t r and t f < 4ns l 60 100 ns power supply generator v cc2 Cgnd2 supply start-up time (0v to 4.5v) on v l , no load l 250 500 s switching characteristics the l denotes the speci? cations which apply over the full operating temperature range, otherwise speci? cations are at t a = 25c. LTM2881-3 v cc = 3.3v, LTM2881-5 v cc = 5.0v, v l = 3.3v, gnd = gnd2 = 0v, on = v l unless otherwise noted.
LTM2881 6 2881p temperature (c) receiver skew (ns) 2.0 0 0.5 1.5 1.0 C0.5 C1.0 2881 g01 100 75 50 25 0 C25 C50 receiver skew vs temperature driver skew vs temperature driver propagation delay vs temperature temperature (c) driver skew (ns) 2.0 0 0.5 1.5 1.0 C0.5 C1.0 2881 g02 100 75 50 25 0 C25 C50 temperature (c) driver prop delay (ns) 80 50 70 65 60 55 75 2881 g03 100 75 50 25 0 C25 C50 typical performance characteristics receiver output voltage vs output current (source and sink) receiver propagation delay vs temperature supply current vs data rate r term vs temperature driver output low/high voltage vs output current driver differential output voltage vs temperature temperature (c) resistance () 130 110 112 114 116 118 120 122 124 126 128 2881 g04 100 75 50 25 0 C25 C50 output current (ma) output voltage (v) 5.0 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 2881 g05 70 60 50 40 30 20 10 0 output high output low temperature (c) output voltage (v) 6 1 0 2 4 3 5 2881 g06 100 75 50 25 0 C25 C50 r = r = 100 r = 54 t a = 25c, LTM2881-3 v cc = 3.3v, LTM2881-5 v cc = 5.0v, v l = 3.3v unless otherwise noted. output current (ma) output voltage (v) 4 1 0 2 3 2881 g07 5 4 3 2 1 0 sink source temperature (c) receiver prop delay (ns) 120 115 110 105 100 95 90 2881 g08 100 75 50 25 0 C25 C50 data rate (mbps) supply current (ma) 200 180 140 160 100 120 80 60 40 20 0 2881 g09 10 1 0.1 r = 54 (C3) r = 100 (C3) r = 54 (C5) r = 100 (C5) r = (C3) r = (C5)
LTM2881 7 2881p typical performance characteristics t a = 25c, LTM2881-3 v cc = 3.3v, LTM2881-5 v cc = 5.0v, v l = 3.3v unless otherwise noted. v cc2 vs load current v cc supply current vs temperature at i load = 100ma on v cc2 v cc2 surplus current vs temperature temperature (c) i cc current (ma) 350 250 300 200 150 100 50 0 2881 g10 100 75 50 25 C25 0 C50 LTM2881-3 LTM2881-5 temperature (c) surplus current (ma) 250 200 150 100 50 0 2881 g11 100 75 50 25 C25 0 C50 LTM2881-5 (rs485 60ma) LTM2881-3 (rs485 60ma) LTM2881-3 (rs485 90ma) LTM2881-5 (rs485 90ma) v cc2 load current (ma) voltage (v) 6 4 5 3 2 2881 g12 180 160 10 20 40 60 80 100 120 140 LTM2881-5 LTM2881-3 i cc 2 output current (ma) 0 10 efficiency (%) 60 50 40 30 20 70 200 50 100 2881 g13 150 LTM2881-5 LTM2881-3 1000s/div 2881 g14 v cc2 100mv/div i load 50ma/div 200s/div 2881 g15 10mv/div v cc2 power ef? ciency v cc2 load step (100ma) v cc2 noise
LTM2881 8 2881p logic side (v cc , v l , gnd) d out (pin a1): general purpose logic output. logic output connected through isolation path to d in . under the condition of an isolation communication failure d out is in a high impedance state. te (pin a2): terminator enable. a logic high enables a termination resistor (typically 120) between pins a and b. di (pin a3): driver input. if the driver outputs are enabled (de high), then a low on di forces the driver noninverting output (y) low and the inverting output (z) high. a high on di, with the driver outputs enabled, forces the driver noninverting output (y) high and inverting output (z) low. de (pin a4): driver enable. a logic low disables the driver leaving the outputs y and z in a high impedance state. a logic high enables the driver. re (pin a5): receiver enable. a logic low enables the receiver output. a logic high disables ro to a high impedance state. ro (pin a6): receiver output. if the receiver output is ena bled ( re low) and if a C b is > 200mv, ro is a logic high, if a C b is < 200mv ro is a logic low. if the receiver inputs are open, shorted, or terminated without a valid signal, ro will be high. under the condition of an isolation communication failure ro is in a high impedance state. v l (pin a7): logic supply. interface supply voltage for pins ro, re , te, di, de, d out , and on. recommended operating voltage is 1.62v to 5.5v. on (pin a8): enable. enables power and data communication through the isolation barrier. if on is high the part is enabled and power and communications are functional to the isolated side. if on is low the logic side is held in reset and the isolated side is unpowered. gnd (pins b1-b5): circuit ground. v cc (pins b6-b8): supply voltage. recommended operating voltage is 3v to 3.6v for LTM2881-3 and 4.5v to 5.5v for LTM2881-5. pin functions isolated side (v cc2 , gnd2) d in (pin l1): general purpose isolated logic input. logic input on the isolated side relative to v cc2 and gnd2. a logic high on d in will generate a logic high on d out . a logic low on d in will generate a logic low on d out . slo (pin l2): driver slew rate control. a low input, relative to gnd2, will force the driver into a reduced slew rate mode for reduced emi. a high input, relative to gnd2, puts the driver into full speed mode to support maximum data rates. y (pin l3): non inverting driver output. high impedance when the driver is disabled. z (pin l4): inverting driver output. high impedance when the driver is disabled. b (pin l5): inverting receiver input. impedance is > 96k in receive mode with te low or unpowered. a (pin l6): non inverting receiver input. impedance is > 96k in receive mode with te low or unpowered. v cc2 (pins l7-l8): isolated supply voltage. internally generated from v cc by an isolated dc/dc converter and regulated to 5v. gnd2 (pins k1-k8): isolated side circuit ground. the pads should be connected to the isolated ground and/or cable shield.
LTM2881 9 2881p block diagram 120 a y te re ro 2.2f 2.2f 2.2f v cc v l gnd d out z slo d in b 2 8 8 1 b d v cc2 isolated dc/dc converter on di de = logic side common = isolated side common gnd2 isolated comm interface isolated comm interface 5v reg rx dx test circuits C + driver di gnd or v l r 2881 f01 y z r v oc C + v od driver di gnd or v l 2881 f02 y z + C i osd C7v to 12v + C receiver 2881 f03 a or b v in i in b or a v in i in r in = figure 1. driver dc characteristics figure 2. driver output short-circuit current figure 3. receiver input current and input resistance
LTM2881 10 2881p a b v cm v ab /2 v ab /2 ro c l 2881 f06a receiver t plhr t phlr 90% 0 90% 10% t r 90% 10% t f 90% 1/2 v l 1/2 v l t rr t fr 10% 2881 f06b 10% v ab v l 0 Cv ab ro a-b figure 6. receiver propagation delay measurements driver di v l or gnd gnd or v cc2 v cc2 or gnd r l r l c l 2881 f05a y z de c l t zld t zhd t hzd t lzd 1/2 v l 1/2 v cc2 1/2 v cc2 de y or z z or y v l v cc2 0v 0v 0.5v 0.5v 2881 f05b figure 5. driver enable and disable timing measurements test circuits driver di r diff c l c l 2881 f04a y z 1/2 v od 90% 90% 00 10% 2881 f04b 10% v od v l y, z di (y-z) 0v t skewd t plhd t rd t fd t phld figure 4. driver timing measurement
LTM2881 11 2881p test circuits a b 0v or v cc2 v cc2 or 0v ro re c l r l v l or gnd 2881 f07a receiver t zlr t zhr t hzr t lzr 1/2 v l 1/2 v l 1/2 v l re ro ro v l v l v ol v oh 0v 0v 0.5v 0.5v 2881 f07b figure 7. receiver enable/disable time measurements t rten t rtz v l b a i a te 2881 f08 receiver 90% 10% 0v te + C + C v ab v b r te = i a v ab 1/2 v l ro i a figure 8. termination resistance and timing measurements functional table logic inputs mode a, b y, z ro dc/dc converter terminator on re te de 1 0 0 0 receive r in hi-z enabled on off 1 0 0 1 transceiver r in driven enabled on off 1 1 0 1 transmit r in driven hi-z on off 1 0 1 0 receive + term on r te hi-z enabled on on 0xxx off r in hi-z hi-z off off
LTM2881 12 2881p overview the LTM2881 module transceiver provides a galvanically- isolated robust rs485/rs422 interface, powered by an integrated, regulated dc/dc converter, complete with decoupling capacitors. a switchable termination resistor is integrated at the receiver input to provide proper termination to the rs485 bus. the LTM2881 is ideal for use in networks where grounds can take on different voltages. isolation in the LTM2881 blocks high voltage differences and eliminates ground loops and is extremely tolerant of common mode transients between ground potentials. error free operation is maintained through common mode events greater than 30kv/s providing excellent noise isolation. dc/dc converter the LTM2881 contains a fully integrated isolated dc/dc converter, including the transformer, so that no external components are necessary. the logic side contains a full-bridge driver, running at 1.6mhz, and is ac-coupled to a single transformer primary. a series dc blocking capacitor prevents transformer saturation due to driver duty cycle imbalance. the transformer scales the primary voltage, and is recti? ed by a full-wave voltage doubler. this topology eliminates transformer saturation caused by secondary imbalances. applications information the dc/dc converter is connected to a low dropout reg- ulator (ldo) to provide a regulated low noise 5v output. the internal power solution is suf? cient to support the transceiver interface at its maximum speci? ed load and data rate, and external pins are supplied for extra decoupling (optional) and heat dissipation. the logic supplies, v cc and v l have a 2.2f decoupling capacitance to gnd and the isolated supply v cc2 has a 2.2f decoupling capacitance to gnd2 within the module package. surplus current is available to external applications. the amount of surplus current is dependent upon the implementation and current delivered to the rs485 driver and line load. an example of available surplus current is shown in the typical performance characteristics graph, v cc2 surplus current vs temperature. driver the driver provides full rs485 and rs422 compatibility. when enabled, if di is high, yCz is positive. when the driver is disabled, both outputs are high impedance with less than 10a of leakage current over the entire common mode range of C7v to 12v, with respect to gnd2.
LTM2881 13 2881p driver overvoltage and overcurrent protection the driver outputs are protected from short circuits to any voltage within the absolute maximum range of (v cc2 C15v) to (gnd2 +15v) levels. the maximum v cc2 current in this condition is 250ma. if the pin voltage exceeds about 10v, current limit folds back to about half of the peak value to reduce overall power dissipation and avoid damaging the part. the device also features thermal shutdown protection that disables the driver and receiver output in case of excessive power dissipation (see note 4 in the electrical characteristics section). slo mode the LTM2881 features a logic-selectable reduced slew rate mode ( slo mode) that softens the driver output edges to reduce emi emissions from equipment and data cables. the reduced slew rate mode is entered by taking the slo pin low to gnd2, where the data rate is limited to about 250kbps. slew limiting also mitigates the adverse effects of imperfect transmission line termination caused by stubs or mismatched cables. figures 9a and 9b show the frequency spectrums of the LTM2881 driver outputs in normal and slo mode operating at 250kbps. slo mode signi? cantly reduces the high frequency harmonics. receiver and failsafe with the receiver enabled, when the absolute value of the differential voltage between the a and b pins is greater than 200mv, the state of ro will re? ect the polarity of (a-b). during data communication the receiver detects the state of the input with symmetric thresholds around 0v. the symmetric thresholds preserve duty cycle for attenuated signals with slow transition rates on high capacitive busses, or long cable lengths. the receiver incorporates a failsafe feature that guarantees the receiver output to be a logic- high during an idle bus, when the inputs are shorted, left open or terminated, but not driven. the failsafe feature eliminates the need for system level integration of network pre-biasing by guaranteeing a logic-high on ro under applications information figure 9a. frequency spectrum slo mode 125khz input figure 9b. normal mode frequency spectrum 125khz input frequency 1.25mhz/div y-z 10db/div 2881 f09a 12.5 6.25 0 frequency 1.25mhz/div y-z 10db/div 2881 f09b 12.5 6.25 0 the conditions of an idle bus. further network biasing constructed to condition transient noise during an idle state is unnecessary due to the common mode transient rejection of the LTM2881. the failsafe detector monitors a and b in parallel with the receiver and detects the state of the bus when a-b is above the input failsafe threshold for longer than about 3s with a hysteresis of 25mv. this failsafe feature is guaranteed to work for inputs spanning the entire common mode range of C7v to 12v. the receiver output is internally driven high (to v l ) or low (to gnd) with no external pull-up needed. when the receiver is disabled the ro pin becomes hi-z with leakage of less than 1a for voltages within the supply range.
LTM2881 14 2881p figure 10. equivalent input resistance into a and b 60 60 a te b 2881 f10 >96k >96k applications information receiver input resistance the receiver input resistance from a or b to gnd2 is greater than 96k permitting up to a total of 256 receivers per system without exceeding the rs485 receiver loading speci? cation. the input resistance of the receiver is unaffected by enabling/disabling the receiver or by powering/unpowering the part. the equivalent input resistance looking into a and b is shown in figure 10. figure 13. termination magnitude and phase vs frequency figure 12. termination resistance vs common mode voltage figure 11. curve trace between a and b with termination enabled and disabled switchable termination proper cable termination is very important for signal ? delity. if the cable is not terminated with its characteristic impedance, re? ections will distort the signal waveforms. the integrated switchable termination resistor provides logic control of the line termination for optimal perfor- mance when con? guring transceiver networks. when the te pin is high, the termination resistor is enabled and the differential resistance from a to b is 120. figure 11 shows the i/v characteristics between pins a and b with the termination resistor enabled and disabled. the resistance is maintained over the entire rs485 common mode range of C7v to 12v as shown in figure 12. the integrated termination resistor has a high frequency response which does not limit performance at the maximum speci? ed data rate. figure 13 shows the magnitude and phase of the termination impedance versus frequency. the termination resistor cannot be enabled by te if the device is unpowered, on is low or the LTM2881 is in thermal shutdown. 2881 f11 common mode voltage (v) resistance () 130 128 126 124 122 120 118 116 114 112 110 2881 g11 15 10 5 C5 0 C10 frequency (mhz) magnitude () phase (degrees) 150 140 130 120 110 100 10 0 C10 C20 C30 C40 2881 f13 10 1 0.1 phase magnitude
LTM2881 15 2881p pcb layout isolation considerations the high integration of the LTM2881 makes the pcb board layout very simple. however, to optimize its electrical isolation characteristics and thermal performance, some layout considerations are still necessary. figure 15 is a suggested layout for good thermal performance and to optimize isolation characteristics. ? use large pcb copper areas for high current paths, including v cc , gnd, v cc2 , and gnd2. it helps to minimize the pcb conduction loss and thermal stress. ? the LTM2881 includes 2.2f ceramic decoupling capacitors on v cc to gnd, v l to gnd, and v cc2 to gnd2 supply pins. further decoupling capacitance (10f) can be added within one-quarter inch away from the v cc , v l , and/or v cc2 pin. figure 15. pcb recommended layout slot v cc gnd gnd2 a b z y dl1 slo ro de on v l di te do1 re v cc2 9.48mm 2881 f15 ? if the LTM2881 voltage supply is hot plugged without additional protection, damage may occur. refer to linear technology application note 88, entitled ceramic capacitors can cause overvoltage transients for a detailed discussion of this problem. to protect against hot plug transients use tantalum for aforementioned additional capacitor. ? do not place copper on the pcb between the inner rows of pads. this area must remain open to withstand the rated isolation voltage. the pcb may also be slotted in this area to insure contamination does not compromise the isolation voltage. supply current the static supply current is dominated by power delivered to the termination resistance. power supply current increases with data rate due to capacitive loading. figure 14 shows supply current versus data rate for three different loads for the circuit con? guration of figure 4. figure 14. supply current vs data rate data rate (mbps) 2881 f14 10 1 0.1 supply current (ma) 250 230 210 190 170 150 130 110 90 70 50 LTM2881-3 r=54 cl=1000p r=54 cl=100p r=54 cl=0 LTM2881-5 r=54 cl=1000p r=54 cl=100p r=54 cl=0 applications information
LTM2881 16 2881p applications information figure 16. cable length vs data rate 2881 f16 data rate (bps) cable length (ft) 10k 1m 10m 100k 100m 100 1k 10 10k low-emi mode max data rate rs485 max data rate normal mode max data rate cable length versus data rate for a given data rate, the maximum transmission distance is bounded by the cable properties. a typical curve of cable length versus data rate compliant with the rs485 standard is shown in figure 16. three regions of this curve re? ect different performance limiting factors in data transmission. in the ? at region of the curve, maximum distance is determined by resistive loss in the cable. the downward sloping region represents limits in distance and rate due to the ac losses in the cable. the solid vertical line represents the speci? ed maximum data rate in the rs485 standard. the dashed line at 250kbps shows the maximum data rate when slo is low. the dashed line at 20mbps shows the maximum data rate when slo is high. a v l re de te ro di gnd v cc v cc 2881 ta02 b y z pwr gnd2 LTM2881 galvanic isolation typical applications full-duplex rs485 connection
LTM2881 17 2881p a v l re de te ro di d out d in gnd fault v cc v cc b y z gnd2 330k 2881 ta03 LTM2881 galvanic isolation 2881 ta04 a v cc2 ro v l te re de di d out gnd gnd2 v cc v cc cmos input cmos output b z 1.8v d in pwr on off regulated 5v switched 5v irlml6402 330k LTM2881 galvanic isolation isolated system fault detection switched 5v power with isolated cmos logic connection with low voltage interface typical applications a v l re de ro di gnd v cc v cc b y z pwr gnd2 LTM2881 galvanic isolation y v l re ro de di gnd v cc v ccb 2881 ta04a z a b pwr gnd2 bus inherited LTM2881 10nf 51 51 51 51 10nf galvanic isolation 2 4-wire full duplex self biasing for unshielded cat5 connection
LTM2881 18 2881p notes: 1. dimensioning and tolerancing per asme y14.5m-1994 2. all dimensions are in millimeters ball designation per jesd ms-028 and jep95 5. primary datum -z- is seating plane 4 3 details of pin #1 identifier are optional, but must be located within the zone indicated. the pin #1 identifier may be either a mold or marked feature package top view 4 pin a1 corner x y aaa z aaa z package bottom view 3 see notes suggested pcb layout top view bga 32 0509 rev ? ltmxxxxxx module tray pin 1 bevel package in tray loading orientation component pin a1 detail a pin 1 0.000 0.635 0.635 1.905 1.905 3.175 3.175 4.445 4.445 6.350 6.350 5.080 5.080 0.000 detail a ?b (32 places) f g h l j k e a b c d 21 43 5 6 7 8 detail b substrate 0.27 C 0.37 2.45 C 2.55 // bbb z d a a1 b1 ccc z detail b package side view mold cap z m xy z ddd m z eee 0.630 0.025 ? 32x symbol a a1 a2 b b1 d e e f g aaa bbb ccc ddd eee min 3.14 0.42 2.72 0.70 0.60 nom 3.27 0.45 2.82 0.75 0.63 15.0 11.25 1.27 12.70 8.89 max 3.40 0.48 2.92 0.80 0.66 0.15 0.10 0.20 0.30 0.15 notes dimensions total number of balls: 32 e b e e b a2 f g package description bga package 32-lead (15mm 11.25mm 2.82mm) (reference ltc dwg # 05-08-1851 rev v )
LTM2881 19 2881p information furnished by linear technology corporation is believed to be accurate and reliable. however, no responsibility is assumed for its use. linear technology corporation makes no representation that the interconnection of its circuits as described herein will not infringe on existing patent rights. package description notes: 1. dimensioning and tolerancing per asme y14.5m-1994 2. all dimensions are in millimeters land designation per jesd mo-222 5. primary datum -z- is seating plane 6. the total number of pads: 32 4 3 details of pad #1 identifier are optional, but must be located within the zone indicated. the pad #1 identifier may be either a mold or marked feature detail b detail b substrate mold cap 0.290 C 0.350 2.400 C 2.600 bbb z z package top view 11.25 bsc 15.00 bsc 4 pad a1 corner x y aaa z aaa z package bottom view 3 pads see notes suggested pcb layout top view lga 32 0308 rev ? ltmxxxxxx module tray pin 1 bevel package in tray loading orientation component pin a1 8.89 bsc 1.27 bsc pad 1 0.635 0.635 1.905 1.905 3.175 3.175 4.445 4.445 6.350 6.350 5.080 5.080 0.000 symbol aaa bbb eee tolerance 0.10 0.10 0.05 detail a 0.630 0.025 ? 32x s y x eee detail c 0.630 0.025 ? 32x s y x eee f g h l j k e a b c d 21 43 5 6 7 2.69 C 2.95 detail a 12.70 bsc 8 detail c lga package 32-lead (15mm 11.25mm 2.8mm) (reference ltc dwg # 05-08-1773 rev v )
LTM2881 20 2881p linear technology corporation 1630 mccarthy blvd., milpitas, ca 95035-7417 (408) 432-1900 fax: (408) 434-0507 www.linear.com ? linear technology corporation 2009 lt 0809 ? printed in usa related parts typical application part number description comments ltc1535 isolated rs485 transceiver 2500v rms isolation in surface mount package lt1785 60v fault-protected transceiver half duplex lt1791 60v fault-protected transceiver full duplex ltc2861 20mbps rs485 transceivers with integrated switchable termination full duplex 15kv esd a v l v cc1 re de te ro di gnd v cc v cc1 2881 ta05 b y z 1 pwr gnd2 a v l re de te ro di gnd v cc v cc2 b y z pwr gnd2 a v l re de te ro di gnd v cc v cc3 b y z pwr gnd2 LTM2881 LTM2881 LTM2881 v cc2 2 3 cable shield or ground return galvanic isolation galvanic isolation galvanic isolation 3 multi-node network with end termination and single ground connection on isolation bus

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