� scds189 ? january 2005 description the ts3a5018 is a quad single-pole double-throw (spdt) analog switch that is designed to operate from 2.3 v to 3.6 v. this device can handle both digital and analog signals, and signals up to v + can be transmitted in either direction. applications � sample-and-hold circuit � battery-powered equipment � audio and video signal routing � communication circuits logic control 11 10 7 nc2 soic, ssop, tssop, or tv sop package (top view) 1 2 3 4 5 16 15 14 13 12 in nc1 no1 com1 nc4 en v + no4 com4 6 com2 no2 nc3 no3 8 gnd 9 com3 function table en in no to com, com to no nc to com, com to nc l l off on l h on off h x off off features � low on-state resistance (10 � ) � low charge injection � excellent on-state resistance matching � low total harmonic distortion (thd) � 2.3-v to 3.6-v single-supply operation � control inputs are 5-v tolerant � latch-up performance exceeds 100 ma per jesd 78, class ii � esd performance tested per jesd 22 ? 2000-v human-body model (a114-b, class ii) ? 1000-v charged-device model (c101) summary of characteristics v + = 3.3 v, t a = 25 c configuration quad single pole double throw (4 � spdt) number of channels 4 on-state resistance (r on ) 7 ? on-state resistance match ( ? r on ) 0.3 ? on-state resistance flatness (r on(flat) ) 5 ? turn-on/turn-off time (t on /t off ) 3.5 ns/2 ns charge injection (q c ) 2 pc bandwidth (bw) 300 mhz off isolation (o iso ) ?48 db at 10 mhz crosstalk (x talk ) ?48 db at 10 mhz total harmonic distortion (thd) 0.2% leakage current (i com(off) ) 5 a power-supply current (i + ) 2.5 a package option 16-pin soic, ssop, tssop, or tvsop please be aware that an important notice concerning availability , standard warranty, and use in critical applications of t exas instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. www.ti.com copyright ? 2005, texas instruments incorporated
� scds189 ? january 2005 www.ti.com 2 ordering information t a package (1) orderable p art number top-side marking soic - d tube ts3a5018d ts3a5018 soic - d tape and reel ts3a5018dr ts3a5018 ?40 c to 85 c ssop (qsop) - dbq tape and reel ts3a5018dbqr ya018 ?40 c to 85 c tssop - pw tube ts3a5018pw ya018 tssop - pw tape and reel TS3A5018PWR ya018 tvsop - dgv tape and reel ts3a5018dgvr ya018 (1) package drawings, standard packing quantities, thermal data, symbolization, and pcb design guidelines are available at www .ti.com/sc/package. absolute minimum and maximum ratings (1)(2) over operating free-air temperature range (unless otherwise noted) min max unit v + supply voltage range (3) ?0.5 4.6 v v nc, v no, v com analog voltage range (3)(4) ?0.5 7 v i k analog port diode current v nc , v no, v com < 0 ?50 ma i nc, i no, i com on-state switch current v nc , v no, v com = 0 to 7 v ?64 64 ma v i digital input voltage range (3)(4) ?0.5 7 v i ik digital input clamp current v i < 0 ?50 ma i + continuous current through v + ?100 100 ma i gnd continuous current through gnd ?100 100 ma (5) d package 73 ja package thermal impedance (5) dbq package 90 c/w ja package thermal impedance (5) dgv package 120 c/w pw package 108 t stg storage temperature range ?65 150 c (1) stresses above these ratings may cause permanent damage. exposure to absolute maximum conditions for extended periods may degrade device reliability. these are stress ratings only , and functional operation of the device at these or any other conditions beyo nd those specified is not implied. (2) the algebraic convention, whereby the most negative value is a minimum and the most positive value is a maximum (3) all voltages are with respect to ground, unless otherwise specified. (4) the input and output voltage ratings may be exceeded if the input and output clamp-current ratings are observed. (5) the package thermal impedance is calculated in accordance with jesd 51-7.
� scds189 ? january 2005 www.ti.com 3 electrical characteristics for 3.3-v supply (1) v + = 3 v to 3.6 v, t a = ?40 c to 85 c (unless otherwise noted) parameter symbol test conditions t a v + min typ max unit analog switch analog signal range v com , v nc, v no 0 v + v on-state r on 0 (v nc or v no ) � v + , switch on, 25 c 3 v 7 10 ? (v nc or v no ) v + , i com = ?32 ma, switch on, see figure 13 full 3 v 12 ? on-state resistance match ? r on v nc or v no = 2.1 v, switch on, 25 c 3 v 0.3 0.8 ? ? r on v nc or v no = 2.1 v, i com = ?32 ma, switch on, see figure 13 full 3 v 1 ? on-state resistance r on(flat) 0 (v nc or v no ) � v + , switch on, 25 c 3 v 5 7 ? (v nc or v no ) v + , i com = ?32 ma, switch on, see figure 13 full 3 v 8 ? v nc or v no = 1 v, v com = 3 v, or switch off, 25 c 3.6 v ?0.1 0.05 0.1 nc, no nc no com or v nc or v no = 3 v, v com = 1 v, switch off, see figure 14 full 3.6 v ?0.2 0.2 nc, no off leakage current i nc(off ) i no(off ) v nc or v no = 0 to 3.6 v, v com = 3.6 v to 0, or switch off, 25 c 0 v ?2 0.05 2 a current v com = 3.6 v to 0, or v nc or v no = 3.6 v to 0, v com = 0 to 3.6 v, switch off, see figure 14 full 0 v ?10 10 v com = 1 v, v nc or v no = 3 v, or switch off, 25 c 3.6 v ?0.1 0.05 0.1 com com nc no or v com = 3 v, v nc or v no = 3 v, switch off, see figure 14 full 3.6 v ?0.2 0.2 com off leakage current i com(off ) v com = 0 to 3.6 v, v nc or v no = 3.6 v to 0, or switch off, 25 c 0 v ?2 0.05 2 a current v no = 3.6 v to 0, or v com = 3.6 v to 0, v nc or v no = 0 to 3.6 v, switch off, see figure 14 full 0 v ?10 10 nc, no on leakage i nc(on) v nc or v no = 1 v, v com = open, or switch on, 25 c 3.6 v ?0.1 0.05 0.1 a on leakage current i nc(on) i no(on) nc no com or v nc or v no = 3 v, v com = open, switch on, see figure 15 full 3.6 v ?0.2 0.2 a com on leakage i com(on) v com = 1 v, v nc or v no = open, or switch on, 25 c 3.6 v ?0.1 0.05 0.1 a on leakage current i com(on ) com nc no or v com = 3 v, v nc or v no = open, switch on, see figure 15 full 3.6 v ?0.2 0.2 a digital control inputs (in, en ) ( 2) input logic high v ih full 2 v + v input logic low v il full 0 0.8 v input leakage i ih , i il v i = 5.5 v or 0 25 c 3.6 v ?1 0.05 1 a input leakage current i ih , i il v i = 5.5 v or 0 full 3.6 v ?1 1 a (1) the algebraic convention, whereby the most negative value is a minimum and the most positive value is a maximum (2) all unused digital inputs of the device must be held at v + or gnd to ensure proper device operation. refer to the ti application report, implications of slow or floating cmos inputs , literature number scba004.
� scds189 ? january 2005 www.ti.com 4 electrical characteristics for 3.3-v supply (1) (continued) v + = 3 v to 3.6 v, t a = ?40 c to 85 c (unless otherwise noted) parameter symbol test conditions t a v + min typ max unit dynamic turn-on time t on v com = 2 v, c l = 35 pf, 25 c 3.3 v 2.5 3.5 8 ns turn-on time t on v com = 2 v, r l = 300 ? , c l = 35 pf, see figure 17 full 3 v to 3.6 v 2.5 9 ns turn-off time t off v com = 2 v, c l = 35 pf, 25 c 3.3 v 0.5 2 6.5 ns turn-off time t off v com = 2 v, r l = 300 ? , c l = 35 pf, see figure 17 full 3 v to 3.6 v 0.5 7 ns charge injection q c v gen = 0, r gen = 0 c l = 0.1 nf, see figure 22 25 c 3.3 v 2 pc nc, no off capacitance c nc(off) c no(on) v nc or v no = v + or gnd, switch off, see figure 16 25 c 3.3 v 4.5 pf com off capacitance c com(off) v com = v + or gnd, switch off, see figure 16 25 c 3.3 v 9 pf nc, no on capacitance c nc(on) c no(on) v nc or v no = v + or gnd, switch on, see figure 16 25 c 3.3 v 16 pf com on capacitance c com(on) v com = v + or gnd, switch on, see figure 16 25 c 3.3 v 16 pf digital input capacitance c i v i = v + or gnd, see figure 16 25 c 3.3 v 3 pf bandwidth bw r l = 50 ? , switch on, see figure 18 25 c 3.3 v 300 mhz off isolation o iso r l = 50 ? , f = 10 mhz, switch off, see figure 19 25 c 3.3 v ?48 db crosstalk x talk r l = 50 ? , f = 10 mhz, switch on, see figure 20 25 c 3.3 v ?48 db crosstalk adjacent x talk(adj) r l = 50 ? , f = 10 mhz, switch on, see figure 21 25 c 3.3 v ?81 db total harmonic distortion thd r l = 600 ? , c l = 50 pf, f = 20 hz to 20 khz, see figure 23 25 c 3.3 v 0.21 % supply positive supply i + v i = v + or gnd, switch on or off 25 c 3.6 v 2.5 7 a positive supply current i + v i = v + or gnd, switch on or off full 3.6 v 10 a (1) the algebraic convention, whereby the most negative value is a minimum and the most positive value is a maximum
� scds189 ? january 2005 www.ti.com 5 electrical characteristics for 2.5-v supply (1) v + = 2.3 v to 2.7 v, t a = ?40 c to 85 c (unless otherwise noted) parameter symbol test conditions t a v + min typ max unit analog switch analog signal range v com , v nc, v no 0 v + v on-state r on 0 (v nc or v no ) � v + , switch on, 25 c 2.3 v 12 20 ? (v nc or v no ) v + , i com = ?24 ma, switch on, see figure 13 full 2.3 v 22 ? on-state resistance match ? r on v nc or v no = 1.6 v, switch on, 25 c 2.3 v 0.3 1 ? ? r on v nc or v no = 1.6 v, i com = ?24 ma, switch on, see figure 13 full 2.3 v 2 ? on-state resistance r on(flat) 0 (v nc or v no ) � v + , switch on, 25 c 2.3 v 14 18 ? (v nc or v no ) v + , i com = ?24 ma, switch on, see figure 13 full 2.3 v 20 ? v nc or v no = 0.5 v, v com = 2.2 v , or switch off, 25 c 2.7 v ?0.1 0.05 0.1 nc, no nc no com or v nc or v no = 2.2 v, v com = 0.5 v , switch off, see figure 14 full 2.7 v ?0.2 0.2 nc, no off leakage current i nc(off) , i no(off ) v nc or v no = 0 to 3.6 v, v com = 3. 6 v to 0, or switch off, 25 c 0 v ?2 0.05 2 a current v to 0, or v nc or v no = 3.6 v to 0, v com = 0 to 3.6 v, switch off, see figure 14 full 0 v ?10 10 v com = 0.5 v, v nc or v no = 2.2 v , or switch off, 25 c 2.7 v ?0.1 0.05 0.1 com off leakage i com(off) com nc no or v com = 2.2 v, v nc or v no = 0.5 v , switch off, see figure 14 full 2.7 v ?0.2 0.2 a off leakage current i com(off ) v com = 0 to 3.6 v, v nc = 3.6 v to 0 , or switch off, 25 c 0 v ?2 0.05 2 a current com nc or v com = 3.6 v to 0, v nc = 0 to 3.6 v , switch off, see figure 14 full 0 v ?10 10 nc, no on leakage i nc(on) v nc or v no = 0.5 v, v com = open , or switch on, 25 c 2.7 v ?0.1 0.05 0.1 a on leakage current i nc(on) i no(on) nc no com or v nc or v no = 2.2 v, v com = open , switch on, see figure 15 full 2.7 v ?0.2 0.2 a com on leakage i com(on) v com = 0.5 v, v nc or v no = open , or switch on, 25 c 2.7 v ?0.1 0.05 0.1 a on leakage current i com(on ) com nc no or v com = 2.2 v, v nc or v no = open , switch on, see figure 15 full 2.7 v ?0.2 0.2 a digital control inputs (in, en ) (2) input logic high v ih full 1.7 v + v input logic low v il full 0 0.7 v input leakage i ih , i il v i = 5.5 v or 0 25 c 2.7 v ?0.1 0.05 0.1 a input leakage current i ih , i il v i = 5.5 v or 0 full 2.7 v ?1 1 a (1) the algebraic convention, whereby the most negative value is a minimum and the most positive value is a maximum (2) all unused digital inputs of the device must be held at v + or gnd to ensure proper device operation. refer to the ti application report, implications of slow or floating cmos inputs , literature number scba004.
� scds189 ? january 2005 www.ti.com 6 electrical characteristics for 2.5-v supply (1) (continued) v + = 2.3 v to 2.7 v, t a = ?40 c to 85 c (unless otherwise noted) parameter symbol test conditions t a v + min typ max unit dynamic turn-on time t on v com = 1.5 v, c l = 35 pf, 25 c 2.5 v 2.5 5 9.5 ns turn-on time t on v com = 1.5 v, r l = 300 ? , c l = 35 pf, see figure 17 full 2.3 v to 2.7 v 2.5 10.5 ns turn-off time t off v com = 1.5 v, c l = 35 pf, 25 c 2.5 v 0.5 3 7.5 ns turn-off time t off v com = 1.5 v, r l = 300 ? , c l = 35 pf, see figure 17 full 2.3 v to 2.7 v 0.5 9 ns charge injection q c v gen = 0, r gen = 0 c l = 0.1 nf, see figure 22 25 c 2.5 v 1 pc nc, no off capacitance c nc(off) c no(off) v nc or v no = v + or gnd, switch off, see figure 16 25 c 2.5 v 3 pf com off capacitance c com(off) v com = v + or gnd, switch off, see figure 16 25 c 2.5 v 9 pf nc, no on capacitance c nc(on) c no(on) v nc or v no = v + or gnd, switch on, see figure 16 25 c 2.5 v 16 pf com on capacitance c com(on) v com = v + or gnd, switch on, see figure 16 25 c 2.5 v 16 pf digital input capacitance c i v i = v + or gnd, see figure 16 25 c 2.5 v 3 pf bandwidth bw r l = 50 ? , switch on, see figure 18 25 c 2.5 v 300 mhz off isolation o iso r l = 50 ? , f = 10 mhz, switch off, see figure 19 25 c 2.5 v ?48 db crosstalk x talk r l = 50 ? , f = 10 mhz, switch on, see figure 20 25 c 2.5 v ?48 db crosstalk adjacent x talk(adj) r l = 50 ? , f = 10 mhz, switch on, see figure 21 25 c 3.3 v ?81 db total harmonic distortion thd r l = 600 ? , c l = 50 pf, f = 20 hz to 20 khz, see figure 23 25 c 2.5 v 0.33 % supply positive supply i + v i = v + or gnd, switch on or off 25 c 2.7 v 2.5 7 a positive supply current i + v i = v + or gnd, switch on or off full 2.7 v 10 a (1) the algebraic convention, whereby the most negative value is a minimum and the most positive value is a maximum
� scds189 ? january 2005 www.ti.com 7 typical performance 0 2 4 6 8 10 12 14 16 18 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 figure 1. r on vs v com v cc = 2.5 v v com (v) r on � ? � v cc = 3.3 v t a = 25 � c 0 2 4 6 8 10 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 figure 2. r on vs v com (v + = 3.3 v) v com (v) r on ��� 85 � c 25 � c ?40 � c 0 2 4 6 8 10 12 14 16 18 0.0 0.5 1.0 1.5 2.0 2.5 3.0 85 � c 25 � c ?40 � c figure 3. r on vs v com (v + = 3.3 v) v com (v) r on ( � ) 0 10 20 30 40 ?60 ?40 ?20 0 20 40 60 80 10 0 t a ( c) leakage current (na) figure 4. leakage current vs temperature (v + = 3.6 v) i nc(on) i no(on) i no(off) i com(on) i com(off) i nc(off) 0 1 2 3 4 5 01234 figure 5. charge-injection (q c ) vs v com charge injection (pc) v + = 3.3 v v + = 2.5 v v com (v) 0 1 2 3 4 5 6 7 2.0 2.5 3.0 3.5 4.0 v + (v) t on /t off (ns) figure 6. t on and t off vs supply voltage t on t off
� scds189 ? january 2005 www.ti.com 8 typical performance 0 1 2 3 4 5 6 7 8 figure 7. t on and t off vs temperature (v + = 5 v) ?40 25 85 t on /t off (ns) t a ( � c) t on t off 0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.0 2.2 2.4 2.6 2.8 3.0 3.2 3.4 3.6 3.8 4.0 figure 8. logic-level threshold vs v + v + (v) logic level threshold (v) v ih v il t a = 25 � c ?7 ?6 ?5 ?4 ?3 ?2 ?1 0 1 10 100 1k figure 9. gain vs frequency bandwidth (v + = 3.3 v) gain (db) frequency (mhz) ?90 ?80 ?70 ?60 ?50 ?40 ?30 ?20 ?10 0 1 10 100 1k figure 10. off isolation vs frequency (v + = 3.3 v) gain (db) frequency (mhz) 0.00 0.05 0.10 0.15 0.20 0.25 0.30 0.35 0.40 0.45 figure 11. total harmonic distortion vs frequency thd (%) frequency (mhz) 10 100 100 k 1000 10 k i + ( a) 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 figure 12. power-supply current vs temperature (v + = 3.3 v) ?40 25 85 t a ( � c)
� scds189 ? january 2005 www.ti.com 9 pin description pin number name description 1 in digital control pin to select between nc and no 2 nc1 normally closed 3 no1 normally open 4 com1 common 5 nc2 normally closed 6 no2 normally open 7 com2 common 8 gnd digital ground 9 com3 common 10 no3 normally open 11 nc3 normally closed 12 com4 common 13 no4 normally open 14 nc4 normally closed 15 en chip enable (active low) 16 v + power supply
� scds189 ? january 2005 www.ti.com 10 parameter description symbol description v com voltage at com v nc voltage at nc v no voltage at no r on resistance between com and nc or no ports when the channel is on ? r on difference of r on between channels in a specific device r on(flat) difference between the maximum and minimum value of r on in a channel over the specified range of conditions i nc(off) leakage current measured at the nc port, with the corresponding channel (nc to com) in the off state i nc(on) leakage current measured at the nc port, with the corresponding channel (nc to com) in the on state and the output (com) open i no(off) leakage current measured at the no port, with the corresponding channel (no to com) in the off state i no(on) leakage current measured at the no port, with the corresponding channel (no to com) in the on state and the output (com) open i com(off) leakage current measured at the com port, with the corresponding channel (com to nc or no) in the off state i com(on) leakage current measured at the com port, with the corresponding channel (com to nc or no) in the on state and the output (nc or no) open v ih minimum input voltage for logic high for the control input (in, en ) v il maximum input voltage for logic low for the control input (in, en ) v i voltage at the control input (in, en ) i ih , i il leakage current measured at the control input (in, en ) t on turn-on time for the switch. this parameter is measured under the specified range of conditions and by the propagation delay between the digital control (in) signal and analog output (nc or no) signal when the switch is turning on. t off turn-off time for the switch. this parameter is measured under the specified range of conditions and by the propagation delay between the digital control (in) signal and analog output (nc or no) signal when the switch is turning off. q c charge injection is a measurement of unwanted signal coupling from the control (in) input to the analog (nc or no) output. this is measured in coulomb (c) and measured by the total charge induced due to switching of the control input. charge injection, q c = c l ? v com , c l is the load capacitance, and ? v com is the change in analog output voltage. c nc(off) capacitance at the nc port when the corresponding channel (nc to com) is off c nc(on) capacitance at the nc port when the corresponding channel (nc to com) is on c no(off) capacitance at the nc port when the corresponding channel (no to com) is off c no(on) capacitance at the nc port when the corresponding channel (no to com) is on c com(off) capacitance at the com port when the corresponding channel (com to nc) is off c com(on) capacitance at the com port when the corresponding channel (com to nc) is on c i capacitance of control input (in, en ) o iso off isolation of the switch is a measurement of off-state switch impedance. this is measured in db in a specific frequency, with the corresponding channel (nc to com) in the off state. x talk crosstalk is a measurement of unwanted signal coupling from an on channel to an off channel (nc1 to no1). adjacent crosstalk is a measure of unwanted signal coupling from an on channel to an adjacent on channel (nc1 to nc2) .this is measured in a specific frequency and in db. bw bandwidth of the switch. this is the frequency in which the gain of an on channel is ?3 db below the dc gain. thd total harmonic distortion describes the signal distortion caused by the analog switch. this is defined as the ratio of root mea n square (rms) value of the second, third, and higher harmonic to the absolute magnitude of the fundamental harmonic. i + static power-supply current with the control (in) pin at v + or gnd
� scds189 ? january 2005 www.ti.com 11 parameter measurement information v + i com r on � v com � v no or v nc i com � gnd channel on nc v i no com v com v i = v ih or v il v no v nc in or en + + figure 13. on-state resistance (r on ) channel off v com =v + to 0 off-state leakage current and v i = v ih or v il v nc or v no = 0 to v + v + gnd nc v i no com v com v no v nc + + + in or en figure 14. off-state leakage current (i com(off) , i nc(off), i no(off ) channel on on-state leakage current v i = v ih or v il v + gnd nc v i no com v com v no v nc + + in or en figure 15. on-state leakage current (i com(on) , i nc(on) )
� scds189 ? january 2005 www.ti.com 12 v + gnd v bias v i v i = v ih or v il v bias = v + or gnd capacitance is measured at nc, no, com, and in inputs during on and off conditions. capacitance meter v com v no v nc com no nc in or en figure 16. capacitance (c i , c com(off) , c com(on) , c nc(off) , c nc(on) ) c l (2) r l v com v + gnd nc or no v nc or v no v i com logic input (1) 300 ? r l c l 35 pf t on test 300 ? 35 pf t off 50% t on t off 50% 90% 90% logic input (v i ) v + switch output (v nc ) 0 in or en (3) r l c l (2) nc or no (1) all input pulses are supplied by generators having the following characteristics: prr 10 mhz, z o = 50 ? , t r < 5 ns, t f < 5 ns. (2) c l includes probe and jig capacitance. (3) see electrical characteristics for v com . figure 17. turn-on (t on ) and turn-off time (t off ) v + gnd nc v i com 50 � 50 � v nc v com channel on: nc to com network analyzer setup source power = 0 dbm (632-mv p-p at 50- � load) dc bias = 350 mv network analyzer source signal + v i = v + or gnd in or en v no no figure 18. bandwidth (bw)
� scds189 ? january 2005 www.ti.com 13 nc com v nc v com channel off: nc to com network analyzer setup source power = 0 dbm (632-mv p-p at 50- � load) dc bias = 350 mv 50 � v + gnd 50 � 50 � network analyzer source signal v i + v i = v + or gnd in or en v no no figure 19. off isolation (o iso ) nc no 50 � 50 � v nc v com channel on: nc to com network analyzer setup source power = 0 dbm (632-mv p-p at 50- � load) dc bias = 350 mv 50 � v + gnd v no source signal channel off: no to com network analyzer v i + v i = v + or gnd in or en figure 20. crosstalk (x talk ) nc1 nc2 50 � 50 � com1 channel on: nc to com network analyzer setup source power = 0 dbm (632 mv p-p at 50 � load) dc bias = 350 mv 50 � v + gnd source signal network analyzer com2 in or en v i + v nc1 v nc2 figure 21. crosstalk adjacent
� scds189 ? january 2005 www.ti.com 14 v + gnd nc or no r gen v i nc or no com v com c l (1) off v com on off ? v com v gen + v i = v ih or v il c l = 0.1 nf v gen = 0 to v + r gen = 0 q c = c l ? v com logic input (2) v ih v il logic input (v i) in or en (1) c l includes probe and jig capacitance. (2) all input pulses are supplied by generators having the following characteristics: prr 10 mhz, z o = 50 ? , t r < 5 ns, t f < 5 ns. figure 22. charge injection (q c ) v + gnd nc com 10 � f c l (1) r l v + /2 10 � f in or en v i + 600 � 600 � 600 � audio analyzer source signal no v source = v + p-p f source = 20 hz to 20 khz channel on: com to nc v i = v ih or v il (1) c l includes probe and jig capacitance. figure 23. total harmonic distortion (thd)
mechanical data mpds006c february 1996 revised august 2000 post office box 655303 ? dallas, texas 75265 dgv (r-pdso-g**) plastic small-outline 24 pins shown 14 3,70 3,50 4,90 5,10 20 dim pins ** 4073251/e 08/00 1,20 max seating plane 0,05 0,15 0,25 0,50 0,75 0,23 0,13 112 24 13 4,30 4,50 0,16 nom gage plane a 7,90 7,70 38 24 16 4,90 5,10 3,70 3,50 a max a min 6,60 6,20 11,20 11,40 56 9,60 9,80 48 0,08 m 0,07 0,40 0 � 8 notes: a. all linear dimensions are in millimeters. b. this drawing is subject to change without notice. c. body dimensions do not include mold flash or protrusion, not to exceed 0,15 per side. d. falls within jedec: 24/48 pins mo-153 14/16/20/56 pins mo-194
mechanical data mtss001c january 1995 revised february 1999 post office box 655303 ? dallas, texas 75265 pw (r-pdso-g**) plastic small-outline package 14 pins shown 0,65 m 0,10 0,10 0,25 0,50 0,75 0,15 nom gage plane 28 9,80 9,60 24 7,90 7,70 20 16 6,60 6,40 4040064/f 01/97 0,30 6,60 6,20 8 0,19 4,30 4,50 7 0,15 14 a 1 1,20 max 14 5,10 4,90 8 3,10 2,90 a max a min dim pins ** 0,05 4,90 5,10 seating plane 0 8 notes: a. all linear dimensions are in millimeters. b. this drawing is subject to change without notice. c. body dimensions do not include mold flash or protrusion not to exceed 0,15. d. falls within jedec mo-153
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