Representative Schematic Diagram. Standard Application ORDERING INFORMATION DEVICE TYPE/NOMINAL VOLTAGE MOTOROLA ANALOG IC DEVICE DATA

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Chad Wilkerson
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1 The 7800, eries of positive voltage regulators are inexpensive, easytouse devices suitable for a multitude of applications that require a regulated supply of up to 00 m. ike their higher powered 7800 and 7800 eries cousins, these regulators feature internal current limiting and thermal shutdown making them remarkably rugged. o external components are required with the 7800 devices in many applications. These devices offer a substantial performance advantage over the traditional zener dioderesistor combination, as output impedance and quiescent current are substantially reduced. Wide Range of vailable, ixed Output Voltages ow ost Internal hort ircuit urrent imiting Internal Thermal Overload Protection o xternal omponents Required omplementary egative Regulators Offered (7900 eries) vailable in either ±5% () or ±0% () elections 5k Z Q 3.8k.2k 420 evice 78XX* Q2 Representative chematic iagram Q4 Q3 Q6 Q5.9k 9k 2.2k Q7.0k Q8 Q9 Q0 ORRI IORTIO Operating Temperature Range Q 5.0k Q k 2.85k Input Output round Package OP8 78XXP T = 0 to +25 Plastic Power 78XXP 78XX* 78XXP* XX indicates nominal voltage *vailable in 5, 8, 9, 2 and 5 V devices. T = 40 to +25 Plastic Power OP8 Plastic Power P IX 29 8 Pin. Output Input Pin. Vout IX PTI P 75 (OP8)* Vin * OP8 is an internally modified O8 package. Pins 2, 3, 6, and 7 are electrically common to the die attach flag. This internal lead frame modification decreases package thermal resistance and increases power dissipation capability when appropriately mounted on a printed circuit board. OP8 conforms to all external dimensions of the standard O8 package. Input in* 0.33µ tandard pplication 78XX Output O** common ground is required between the input and the output voltages. The input voltage must remain typically 2.0 V above the output voltage even during the low point on the input ripple voltage. *in is required if regulator is located an *appreciable distance from power supply filter. **O is not needed for stability; however, it does *improve transient response. VI TYP/OI VOT 0% 5% Voltage OTORO O I VI T 397

2 7800, eries XI RTI (T = +25, unless otherwise noted.) Rating ymbol Value nit Input Voltage (2.6 V8.0 V) Input Voltage (2 V8 V) Input Voltage (24 V) VI torage Temperature Range Tstg 65 to +50 Operating unction Temperature Range T 0 to +50 TRI RTRITI (VI = 0 V, IO = 40 m, I = 0.33 µ, O = 0. µ, 40 < T < +25 (for 78XX), 0 < T < +25 (for 78XX), unless otherwise noted.) Vdc 7805, 7805 haracteristics ymbol in Typ ax in Typ ax nit Output Voltage (T = +25 ) VO Vdc ine Regulation Regline mv (T = +25, IO = 40 m) 7.0 Vdc VI 20 Vdc Vdc VI 20 Vdc oad Regulation (T = +25,.0 m IO 00 m) (T = +25,.0 m IO 40 m) Output Voltage (7.0 Vdc VI 20 Vdc,.0 m IO 40 m) (VI = 0 V,.0 m IO 70 m) Input ias urrent (T = +25 ) (T = +25 ) Input ias urrent hange (8.0 Vdc VI 20 Vdc) (.0 m IO 40 m) Output oise Voltage (T = +25, 0 z f 00 kz) Ripple Rejection (IO = 40 m, f = 20 z, 8.0 Vdc VI 8 V, T = +25 ) Regload VO II II Vn µv RR d ropout Voltage (T = +25 ) VI VO.7.7 Vdc TRI RTRITI (VI = 4 V, IO = 40 m, I = 0.33 µ, O = 0. µ, 40 < T < +25 (for 78XX), 0 < T < +25 (for 78XX), unless otherwise noted.) 7808, 7808 haracteristics ymbol in Typ ax in Typ ax nit Output Voltage (T = +25 ) VO Vdc ine Regulation Regline mv (T = +25, IO = 40 m) 0.5 Vdc VI 23 Vdc Vdc VI 23 Vdc oad Regulation (T = +25,.0 m IO 00 m) (T = +25,.0 m IO 40 m) Output Voltage (0.5 Vdc VI 23 Vdc,.0 m IO 40 m) (VI = 4 V,.0 m IO 70 m) Input ias urrent (T = +25 ) (T = +25 ) Input ias urrent hange ( Vdc VI 23 Vdc) (.0 m IO 40 m) Output oise Voltage (T = +25, 0 z f 00 kz) Ripple Rejection (IO = 40 m, f = 20 z, 2 V VI 23 V, T = +25 ) Regload VO II II Vn µv RR d ropout Voltage (T = +25 ) VI VO.7.7 Vdc mv Vdc m m mv Vdc m m 398 OTORO O I VI T

3 7800, eries TRI RTRITI (VI = 5 V, IO = 40 m, I = 0.33 µ, O = 0. µ, 40 < T < +25 (for 78XX), 0 < T < +25 (for 78XX), unless otherwise noted.) 7809, 7809 haracteristics ymbol in Typ ax in Typ ax nit Output Voltage (T = +25 ) VO Vdc ine Regulation (T = +25, IO = 40 m).5 Vdc VI 24 Vdc 2 Vdc VI 24 Vdc oad Regulation (T = +25,.0 m IO 00 m) (T = +25,.0 m IO 40 m) Output Voltage (.5 Vdc VI 24 Vdc,.0 m IO 40 m) (VI = 5 V,.0 m IO 70 m) Input ias urrent (T = +25 ) (T = +25 ) Input ias urrent hange ( Vdc VI 23 Vdc) (.0 m IO 40 m) Output oise Voltage (T = +25, 0 z f 00 kz) Regline Regload VO II II Vn µv mv mv Vdc m m Ripple Rejection (IO = 40 m, f = 20 z, 3 V VI 24 V, T = +25 ) ropout Voltage (T = +25 ) RR d VI VO.7.7 Vdc TRI RTRITI (VI = 9 V, IO = 40 m, I = 0.33 µ, O = 0. µ, 40 < T < +25 (for 78XX), 0 < T < +25 (for 78XX), unless otherwise noted.) 782, 782 haracteristics ymbol in Typ ax in Typ ax nit Output Voltage (T = +25 ) VO Vdc ine Regulation (T = +25, IO = 40 m) 4.5 Vdc VI 27 Vdc 6 Vdc VI 27 Vdc oad Regulation (T = +25,.0 m IO 00 m) (T = +25,.0 m IO 40 m) Output Voltage (4.5 Vdc VI 27 Vdc,.0 m IO 40 m) (VI = 9 V,.0 m IO 70 m) Input ias urrent (T = +25 ) (T = +25 ) Input ias urrent hange (6 Vdc VI 27 Vdc) (.0 m IO 40 m) Output oise Voltage (T = +25, 0 z f 00 kz) Regline Regload VO II II Vn µv mv mv Vdc m m Ripple Rejection (IO = 40 m, f = 20 z, 5 V VI 25 V, T = +25 ) ropout Voltage (T = +25 ) RR d VI VO.7.7 Vdc OTORO O I VI T 399

4 7800, eries TRI RTRITI (VI = 23 V, IO = 40 m, I = 0.33 µ, O = 0. µ, 40 < T < +25 (for 78XX), 0 < T < +25 (for 78XX), unless otherwise noted.) 785, 785 haracteristics ymbol in Typ ax in Typ ax nit Output Voltage (T = +25 ) VO Vdc ine Regulation Regline mv (T = +25, IO = 40 m) 7.5 Vdc VI 30 Vdc Vdc VI 30 Vdc oad Regulation (T = +25,.0 m IO 00 m) (T = +25,.0 m IO 40 m) Output Voltage (7.5 Vdc VI 30 Vdc,.0 m IO 40 m) (VI = 23 V,.0 m IO 70 m) Input ias urrent (T = +25 ) (T = +25 ) Input ias urrent hange (20 Vdc VI 30 Vdc) (.0 m IO 40 m) Output oise Voltage (T = +25, 0 z f 00 kz) Ripple Rejection (IO = 40 m, f = 20 z, 8.5 V VI 28.5 V, T = +25 ) ropout Voltage (T = +25 ) Regload VO II II Vn µv RR d VI VO.7.7 Vdc TRI RTRITI (VI = 27 V, IO = 40 m, I = 0.33 µ, O = 0. µ, 0 < T < +25, unless otherwise noted.) haracteristics ymbol in Typ ax in Typ ax nit Output Voltage (T = +25 ) VO Vdc ine Regulation (T = +25, IO = 40 m) 2.4 Vdc VI 33 Vdc 20.7 Vdc VI 33 Vdc 22 Vdc VI 33 Vdc 2 Vdc VI 33 Vdc oad Regulation (T = +25,.0 m IO 00 m) (T = +25,.0 m IO 40 m) Output Voltage (2.4 Vdc VI 33 Vdc,.0 m IO 40 m) (20.7 Vdc VI 33 Vdc,.0 m IO 40 m) (VI = 27 V,.0 m IO 70 m) (VI = 27 V,.0 m IO 70 m) Input ias urrent (T = +25 ) (T = +25 ) Input ias urrent hange (22 Vdc VI 33 Vdc) (2 Vdc VI 33 Vdc) (.0 m IO 40 m) Output oise Voltage (T = +25, 0 z f 00 kz) Ripple Rejection (IO = 40 m, f = 20 z, 23 V VI 33 V, T = +25 ) ropout Voltage (T = +25 ) Regline Regload VO II II Vn µv RR d VI VO.7.7 Vdc mv Vdc m m mv mv Vdc m m 3200 OTORO O I VI T

5 7800, eries TRI RTRITI (VI = 33 V, IO = 40 m, I = 0.33 µ, O = 0. µ, 0 < T < +25, unless otherwise noted.) haracteristics ymbol in Typ ax in Typ ax nit Output Voltage (T = +25 ) VO Vdc ine Regulation (T = +25, IO = 40 m) 27.5 Vdc VI 38 Vdc 28 Vdc VI 80 Vdc 27 Vdc VI 38 Vdc oad Regulation (T = +25,.0 m IO 00 m) (T = +25,.0 m IO 40 m) Output Voltage (28 Vdc VI 38 Vdc,.0 m IO 40 m) (27 Vdc VI 38 Vdc,.0 m IO 40 m) (28 Vdc VI = 33 Vdc,.0 m IO 70 m) (27 Vdc VI 33 Vdc,.0 m IO 70 m) Input ias urrent (T = +25 ) (T = +25 ) Input ias urrent hange (28 Vdc VI 38 Vdc) (.0 m IO 40 m) Output oise Voltage (T = +25, 0 z f 00 kz) Regline Regload VO II II Vn µv mv mv Vdc m m Ripple Rejection (IO = 40 m, f = 20 z, 29 V VI 35 V, T = +25 ) ropout Voltage (T = +25 ) RR d VI VO.7.7 Vdc OTORO O I VI T 320

6 7800, eries I I, IPT I RRT (m) V O, OTPT VOT (V) igure. ropout haracteristics VI, IPT VOT (V) Vout = 5.0 V T = 25 igure 3. Input ias urrent versus mbient Temperature 7805 VI = 0 V VO= 5.0 V IO = 40 m IO = 40 m IO =.0 m IO = 00 m T, IT TPRTR ( ), IPT/OTPT IRTI VOT (V) I V O V I I, IPT I RRT (m) igure 2. ropout Voltage versus unction Temperature IO = 40 m ropout of Regulation is defined as when VO = 2% of VO IO = 70 m T, TIO TPRTR ( ) igure 4. Input ias urrent versus Input Voltage 7805 Vout = 5.0 V IO = 40 m T = 25 IO =.0 m VI, IPT VOT (V) P, POWR IIPTIO (mw) 0,000 igure 5. aximum verage Power issipation versus mbient Temperature TO92 Type Package Rθ = 200 /W P(max) to 25 = 625 mw o eatsink T, IT TPRTR ( ) θ R, TR RIT TIO-TO-IR ( /W) igure 6. OP8 Thermal Resistance and aximum Power issipation versus P... opper ength P(max) for T = 50 raph represents symmetrical layout ÎÎÎ ÎÎÎ ÎÎÎ oz..6 ÎÎÎ opper mm Rθ , T O OPPR (mm) , XI POWR IIPTIO (W) P 3202 OTORO O I VI T

7 7800, eries PPITIO IORTIO esign onsiderations The 7800 eries of fixed voltage regulators are designed with Thermal Overload Protection that shuts down the circuit when subjected to an excessive power overload condition. Internal hort ircuit Protection limits the maximum current the circuit will pass. In many low current applications, compensation capacitors are not required. owever, it is recommended that the regulator input be bypassed with a capacitor if the regulator is connected to the power supply filter with long wire lengths, or if the output load capacitance is large. The input bypass capacitor should be selected to provide good highfrequency characteristics to insure stable operation under all load conditions µ or larger tantalum, mylar, or other capacitor having low internal impedance at high frequencies should be chosen.the bypass capacitor should be mounted with the shortest possible leads directly across the regulators input terminals. ood construction techniques should be used to minimize ground loops and lead resistance drops since the regulator has no external sense lead. ypassing the output is also recommended. igure 7. urrent Regulator igure 8. ± 5 V Tracking Voltage Regulator Input 0.33µ 7805 The 7800 regulators can also be used as a current source when connected as above. In order to minimize dissipation the 7805 is chosen in this application. Resistor R determines the current as follows: IO R onstant urrent to rounded oad +20V 0.33µ 0.33µ 20V P P 70 +VO 0k 0k VO IO = 5.0 V + R I II = 3.8 m over line and load changes or example, a 00 m current source would require R to be a 50 Ω, /2 W resistor and the output voltage compliance would be the input voltage less 7 V. igure 9. Positive and egative Regulator +VI 78XX +VO 0.33µ 0.µ VI 79XX 0.33µ 0.µ VO OTORO O I VI T 3203

8 Tape and Reel Options In rief... otorola offers the convenience of Tape and Reel packaging for our growing family of standard integrated circuit products. Reels are available to support the requirements of both first and second generation pickandplace equipment. The packaging fully conforms to the latest I48 specification. The antistatic embossed tape provides a secure cavity, sealed with a peelback cover tape. Page Tape and Reel onfigurations Tape and Reel Information Table nalog PQ Table OTORO O I VI T 2

9 Tape and Reel onfigurations echanical Polarization OI and icro8 VI Typical P VI Typical PI ser irection of eed ser irection of eed P and 2P VI Typical ser irection of eed OT23 (5 Pin) VI Typical OT89 (3 Pin) VI Typical OT89 (5 Pin) VI Typical ser irection of eed ser irection of eed ser irection of eed 22 OTORO O I VI T

10 Tape and Reel onfigurations (continued) TY (Preferred) TO92 Reel tyles TY arrier trip dhesive Tape Rounded ide arrier trip dhesive Tape lat ide ÉÉÉÉÉÉÉ ÉÉÉÉÉÉÉ eed eed Rounded side of transistor and adhesive tape visible. lat side of transistor and adhesive tape visible. TY P (Preferred) dhesive Tape On Top ide TO92 mmo Pack tyles TY dhesive Tape On Top ide Rounded ide É ÉÉ É eed arrier trip lat ide É eed ÉÉ É arrier trip abel Rounded side of transistor and adhesive tape visible. abel lat side of transistor and adhesive tape visible. tyle P ammo pack is equivalent to tyles and of reel pack dependent on feed orientation from box. tyle ammo pack is equivalent to tyle of reel pack dependent on feed orientation from box. TO92 I Radial Tape in an old ox or On Reel W2 4 5 W W T T 2 T2 P2 P2 P P OTORO O I VI T 23

11 Tape and Reel Information Table Package Tape Width evices() Reel ize evice (mm) per Reel (inch) uffix O8, OP8 2 2,500 3 R2 O4 6 2,500 3 R2 O6 6 2,500 3 R2 O6, O8+8 WI 6,000 3 R2 O20 WI 24,000 3 R2 O24 WI 24,000 3 R2 O28 WI 24,000 3 R2 O28 WI 32,000 3 R3 icro8 2 2,500 3 R2 P20 6,000 3 R2 P R2 P R2 P R2 P R2 P R2 TO226 (TO92)(2) 8 2,000 3 R, R, RP, or R (mmo Pack) only P 6 2,500 3 R 2P R4 OT23 (5 Pin) 8 3,000 7 TR OT89 (3/5 Pin) 2,000 7 T () inimum order quantity is reel. istributors/o customers may break lots or reels at their option, however broken reels may not be returned. (2) Integrated circuits in TO226 packages are available in tyes and only, with optional mmo Pack (uffix RP or R). The R and RP configurations are preferred. or ordering information please contact your local otorola emiconductor ales Office. 24 OTORO O I VI T

12 nalog PQ Table Tape/Reel and mmo Pack P OI icro8 TO92 P 2P OT23 (5 Pin) OT89 (3 Pin) OT89 (5 Pin) Package Type Package ode PQ ase /reel ase /reel ase /reel ase /reel ase /reel ase /reel ase /reel ase /reel ase /reel ase /reel ase /reel ase /reel ase /mmo Pack ase /reel ase /reel ase /reel ase /reel ase /reel OTORO O I VI T 25

13 26 OTORO O I VI T

14 Packaging Information In rief... The packaging availability for each device type is indicated on the individual data sheets and the elector uide. ll of the outline dimensions for the packages are given in this section. The maximum power consumption an integrated circuit can tolerate at a given operating ambient temperature can be found from the equation: T(max) T P(T) = Rθ(Typ) where: P(T) = Power issipation allowable at a given operating ambient temperature. This must be greater than the sum of the products of the supply voltages and supply currents at the worst case operating condition. T(max) = aximum operating unction Temperature as listed in the aximum Ratings ection. ee individual data sheets for T(max) information. T = aximum desired operating mbient Temperature Rθ(Typ) = Typical Thermal Resistance unction-to- mbient OTORO O I VI T 3

15 ase Outline imensions P, P, Z IX (TO-226/TO-92) I R. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. OTOR O P YO IIO R I OTRO. 4. IIO PPI TW P. IIO PPY TW II. IIO I OTRO I P YO IIO II. 2 3 TI X X V P TIO XX I IITR P R V , T IX I Y T TI T. IIOI TORI PR I Y4.5, OTROI IIO: I Y Q P 0.25 (0.00) Y R I IITR Q R T OTORO O I VI T

16 T IX I Q P OPTIO R T TI. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO O OT I ITROT R (R) PROTRIO. IIO II PROTRIO OT X (.092) XI. 5 5X 0.04 (0.356) T P 5X I IITR Q T, TV IX I 5 Q 5X P 0.0 (0.254) T P OPTIO R 5X 0.24 (0.60) T T W V TI. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO O OT I ITROT R (R) PROTRIO. IIO II PROTRIO OT X (.092) XI. I IITR Q V W T IX 340 I Q T TI. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO O OT I ITROT R (R) PROTRIO. IIO II PROTRIO OT X 0.92 (0.043) XI. 5 I IITR Q P (0.04) T Q OTORO O I VI T 33

17 T, T IX I Q 5 P T TI. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO O OT I ITROT R (R) PROTRIO. IIO II PROTRIO OT X 0.92 (0.043) XI. I IITR Q (0.04) T Q T- IX (P) I V R. IIOI TORI PR I Y4.5, OTROI IIO: I T TI I IITR R V P 0.3 (0.005) T T IX (P) I Y 3 4 V R P 0.3 (0.005) T T TI Z. IIOI TORI PR I Y4.5, OTROI IIO: I. I IITR R V Z OTORO O I VI T

18 P,, P, P IX I IIO TO TR O W OR PR. 2. P OTOR OPTIO (RO OR QR ORR). 3. IIOI TORI PR I Y4.5, OT 2 T TI 0.3 (0.005) T IITR I , P, -4, P2 IX I WITI 0.3 (0.005) RI O TR POITIO T TI T XI TRI OITIO. 2. IIO TO TR O W OR PR. 3. IIO O OT I O. 4. RO ORR OPTIO. 4 TI I IITR P2,, P, P IX I R P 0.25 (0.00) T TI T. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO TO TR O W OR PR. 4. IIO O OT I O. 5. RO ORR OPTIO. I IITR OTORO O I VI T 35

19 , P, P2, V IX (IP6) I 6 9. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO TO TR O W OR PR. 4. IIO O OT I O. 5. ITR OTIO TW 4 5, T TI 8 OT 5 6 P 6 P 0.3 (0.005) T I IITR (0.005) T P IX 6480 (IP6) I O P R 3 P 0.25 (0.00) T T TI. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO TO TR O W OR PR. 4. IIO O OT I O PROTRIO. 5. O OR PROTRIO OT X 0.25 (0.00). 6. RO ORR OPTIO. I IITR P R P IX I 24 Q P TI. WITI 0.3 (0.005) RI O TR POITIO T TI T XI TRI OITIO. 2. IIO TO TR O W OR PR. IITR I P Q OTORO O I VI T

20 ,,, P IX I POITIO TOR O (), WITI 0.25 (0.00) T XI TRI OITIO, I RTIO TO TI OTR. 2. IIO TO TR O W OR PR. 3. IIO O OT I O. 8 TI IITR I P IX I 28. POITIO TOR O (), WITI 0.25 (0.00) T XI TRI OITIO, I RTIO TO TI OTR. 2. IIO TO TR O W OR PR. 3. IIO O OT I O IITR I TI P IX 7-03 I POITIO TOR O (), WITI 0.25 (0.00) T XI TRI OITIO, I RTIO TO TI OTR. 2. IIO TO TR O W OR PR. 3. IIO O OT I O. 20 TI IITR I OTORO O I VI T 37

21 , P, P-3 IX (IP24) I T TI P 0.25 (0.00) T 24 P OT 0.25 (0.00) T. R OTOR OPTIO. 2. IIO TO TR O W OR PR. 3. IIOI TORI PR I Y4.5, OTROI IIO: I. I IITR , P, P IX I 20 T TI P 0.25 (0.00) T 20 P 0.25 (0.00) T. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO TO TR O W OR PR. 4. IIO O OT I O. I IITR ,, 2 IX (O-8, OP-8) I R IIOI TORI PR Y4.5, IIO R I IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.5 PR I. 5. IIO O OT I O PROTRIO. OW R PROTRIO 0.27 TOT I X O T IIO T XI TRI OITIO. 8 e 0.25 TI 0.0 h X 45 IITR I I X e h OTORO O I VI T

22 IX (O-4) I 4 T TI P 7 P 7 P 0.25 (0.00) T 0.25 (0.00) R X 45. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.5 (0.006) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.27 (0.005) TOT I X O T IIO T XI TRI OITIO. IITR I P R IX (O-6) I 6 T TI P 0.25 (0.00) T P 8 P 0.25 (0.00) R X 45. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.5 (0.006) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.27 (0.005) TOT I X O T IIO T XI TRI OITIO. IITR I P R W, P IX (O-20, O20) I X (0.25) T 8X 0X P 0.00 (0.25) T TI R X 45. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.50 (0.006) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.3 (0.005) TOT I X O IIO T XI TRI OITIO. IITR I P R OTORO O I VI T 39

23 W IX (O-24, OP (6+4+4)) I 24 T TI X 2 24X 0.00 (0.25) T 22X P 0.00 (0.25) R X 45. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.5 (0.006) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.3 (0.005) TOT I X O IIO T XI TRI OITIO. IITR I P R W IX (O-28, OI28) I X P 0.00 (0.25). IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.5 (0.006) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.3 (0.005) TOT I X O IIO T XI TRI OITIO. 28X 0.00 (0.25) T 26X 4 R X 45 T TI IITR I P R W IX (O-6, OP6, OP-8+8) I X 4X 0.00 (0.25) T 8 8X P T TI 0.00 (0.25) R X 45. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.5 (0.006) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.3 (0.005) TOT I X O IIO T XI TRI OITIO. IITR I P R OTORO O I VI T

24 IX 750 (O6) I O T TI 4 X 0.25 (0.00) T 6 P 0.25 (0.00) R X 45 IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3 IIO O OT I O PROTRIO. 4 XI O PROTRIO 0.5 (0.006) PR I. 5 IIO O OT I R PROTRIO. OW R PROTRIO 0.27 (0.005) TOT I X O T IIO T XI TRI OITIO. IITR I P R W IX 750 (OP6) I O 6 T. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O PROTRIO. 4. XI O PROTRIO 0.5 (0.006) PR I. P 0.00 (0.25) 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.3 (0.005) TOT I 8 X O IIO T XI TRI OITIO. 3X 0.00 (0.25) T IITR I R X P T R TI T X OTORO O I VI T 3

25 762-0 Plastic edium Power Package (IP-9) I 9 T R Q TI V Y 0.25 (0.00) T 9 W 9 P X 0.25 (0.00) T 0.25 (0.00) T. IIOI TORI PR I Y4.5, OTROI IIO: IITR. IITR I Q R V W X Y IX (P-20) I 20 V Y R W (0.80) T (0.80) T Z X 0.00 (0.250) T VIW. T,, TRI WR TOP O OR XIT PTI OY T O PRTI I. 2. IIO, TR POITIO TO R T T T, TI. 3. IIO R O OT I O. OW O I 0.00 (0.250) PR I. 4. IIOI TORI PR I Y4.5, OTROI IIO: I. 6. T P TOP Y R T T P OTTO Y P TO 0.02 (0.300). IIO R R TRI T T OTROT XTR O T PTI OY XIV O O, TI R RR, T RR ITR, T II Y IT TW T TOP OTTO O T PTI OY. 7. IIO O OT I R PROTRIO OR ITRIO. T R PROTRIO() OT T IIO TO RTR T (0.940). T R ITRIO() OT T IIO TO R T (0.635). Z R (0.80) T (0.80) T (0.00) T TI VIW 0.00 (0.250) T VIW (0.80) T (0.80) T I IITR R V W X Y Z OTORO O I VI T

26 IX (P28) I Y R (0.80) T (0.80) T Z 28 V W X VIW 0.00 (0.250) T Z R (0.80) T (0.80) T (0.80) T VIW (0.00) T TI (0.80) T 0.00 (0.250) T VIW. T,, TRI WR TOP O OR XIT PTI OY T O PRTI I. 2. IIO, TR POITIO TO R T T T, TI. 3. IIO R O OT I O. OW O I 0.00 (0.250) PR I. 4. IIOI TORI PR I Y4.5, OTROI IIO: I. 6. T P TOP Y R T T P OTTO Y P TO 0.02 (0.300). IIO R R TRI T T OTROT XTR O T PTI OY XIV O O, TI R RR, T RR ITR, T II Y IT TW T TOP OTTO O T PTI OY. 7. IIO O OT I R PROTRIO OR ITRIO. T R PROTRIO() OT T IIO TO RTR T (0.940). T R ITRIO() OT T IIO TO R T (0.635). I IITR R V W X Y Z OTORO O I VI T 33

27 IX (P) I Y R Z 0.007(0.80) T 0.007(0.80) T X VIW 0.00 (0.25) T 44 V W 0.007(0.80) T Z R 0.00 (0.25) T. T,, R TRI WR TOP O OR XIT PTI OY T O PRTI I. 2. IIO, TR POITIO TO R T T T, TI. 3. IIO R O OT I O. OW O I 0.00 (0.25) PR I. 4. IIOI TORI PR I Y4.5, OTROI IIO: I (0.80) T 0.007(0.80) T VIW (0.0) T TI VIW 6. T P TOP Y R T T P OTTO Y P TO 0.02 (0.300). IIO R R TRI T T OTROT XTR O T PTI OY XIV O O, TI R RR, T RR ITR, T II Y IT TW T TOP OTTO O T PTI OY. 7. IIO O OT I R PROTRIO OR ITRIO. T R PROTRIO() OT T IIO TO RTR T (0.940). T R ITRIO() OT T IIO TO R T (0.635) (0.80) T I IITR R V W X Y Z IX 803 PRIIRY 20 0 P (0.005) 0 20 P 0.3 (0.005) T 0.0 (0.004) T TI 6 IIOI TORI PR I Y4.5, OTROI IIO: IITR. 8 IIO O OT I O PROTRIO. 9 XI O PROTRIO 0.5 (0.008) PR I. 0 IIO O OT I R PROTRIO. OW R PROTRIO 0.3 (0.006) TOT I X O T IIO T XI TRI OITIO. IITR I * 0.488* *PPROXIT 34 OTORO O I VI T

28 TV IX (5-Pin ZIP) I PI 5X R Q P PI (0.254) T P Q Y 5X T TI V (0.60) T. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO R O OT I O OR PROTRIO. 4. IIO O OT I O OR PROTRIO. 5. O OR PROTRIO OT X 0.00 (0.250). 6. IIO O OT I R PROTRIO. OW PROTRIO (0.076) TOT I X O T IIO. T XI TRI OITIO. I IITR R V R R Y T IX I P PI R 5X 7X 5 Q PI (0.254) T P Y T TI 5X (0.60) T. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO R O OT I O OR PROTRIO. 4. IIO O OT I O OR PROTRIO. 5. O OR PROTRIO OT X 0.00 (0.250). 6. T 7. IIO O OT I R PROTRIO. OW PROTRIO (0.076) TOT I X O T IIO. T XI TRI OITIO. I IITR Q R Y R R OTORO O I VI T 35

29 T IX 8240 (TQP44) I O Z T,, Z T T T TI (0.008) Z 0.05 (0.002) Z V 0.20 (0.008) Z PTI ÇÇÇÇ ÉÉÉÉ TI T (0.008) T Z 0.05 (0.002) T 0.20 (0.008) T Z TIO 0.20 (0.008) T Z R W Q X VIW Y TI 0.0 (0.004). IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T T, Z TO TRI T T. 5. IIO V TO TRI T TI. 6. IIO O OT I O PROTRIO. OW PROTRIO I 0.25 (0.00) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. R PROTRIO OT T IIO TO X (0.02). IITR I R 2 R Q 5 5 R V W R R X.000 R R Y 2 R 2 R 36 OTORO O I VI T

30 IX (QP) I (0.008) T,, PI IT 0.20 (0.008) 0.05 (0.002) VIW Y 3 P VIW Y 0.20 (0.008) 0.05 (0.002) V 0.20 (0.008) T PTI ÇÇÇ ÉÉÉ T 0.20 (0.008) T 40X TIO 44 P W Y VIW P T 0.0 (0.004) T. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T, TO TRI T T. 5. IIO V TO TRI T TI T. 6. IIO O OT I O PROTRIO. OW PROTRIO I 0.25 (0.00) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. R PROTRIO OT T IIO TO X (0.02). T VIW P R R R R2 2 IITR I V W Y R 0.08 R R R R R OTORO O I VI T 37

31 IX 8400 I O 64 Z T,, Z T TI 0.20 (0.008) Z T Z (0.002) V 0.20 (0.008) Z T TI P (0.008) (0.002) T 0.20 (0.008) T T Z Z T ÉÉÉ ÇÇ ÉÉÉ ÇÇ ÉÉÉ ÇÇ ÉÉÉ 0.20 (0.008) T Z TIO Y 0.0 (0.004) TI R W TI X Q. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T T, Z TO TRI T T. 5. IIO V TO TRI T TI. 6. IIO O OT I O PROTRIO. OW PROTRIO I 0.25 (0.00 ) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. R PROTRIO OT T IIO TO X (0.04). IITR I R 2 R P Q 5 5 R V W R R X Y.000 R 2 R R 2 R 38 OTORO O I VI T

32 IX (icro8) I 8. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O, PROTRIO OR T RR. O, PROTRIO OR T RR OT X 0.5 (0.006) PR I. 4. IIO O OT I ITR OR PROTRIO. ITR OR PROTRIO OT X 0.25 (0.00) PR I. PI I T TI (0.005) 8 P 0.08 (0.003) T IITR I OTORO O I VI T 39

33 IX (TQP52) I TI 0.20 (0.008) 0.05 (0.002) V 0.20 (0.008) TI,, (0.008) 0.05 (0.002) V 0.20 (0.008) T TI T 0.02 (0.008) TIO 0.0 (0.004) TI T W TI X R Q. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T, TO TRI T T. 5. IIO V TO TRI T TI. 6. IIO O OT I O PROTRIO. OW PROTRIO I 0.25 (0.00) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T IIO T XI TRI OITIO. R OT OT O T OWR RI OR T OOT. IITR I R R Q R T V W X.6 R R 320 OTORO O I VI T

34 IX I 52 4X 4X TIP 0.20 (0.008) 0.20 (0.008) T X X=,, X VIW Y V VIW Y V PTI ÉÉÉ ÉÉÉ ÇÇÇ 0.3 (0.005) T TIO ROTT 90 OWI T 4X θ2 0.0 (0.004) T T TI 4X θ3 VIW (0.002) VIW W θ Z θ 2 X R R 0.25 (0.00). IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T, TO TRI T T. 5. IIO V TO TRI T TI T. 6. IIO O OT I O PROTRIO. OW PROTRIO I 0.25 (0.00) PR I. IIO O I O IT R TRI T T IIO O OT I R PROTRIO. R PROTRIO OT T WIT TO X 0.46 (0.08). II P TW PROTRIO T OR PROTRIO 0.07 (0.003). IITR I R R R V V W 0.20 R R Z.00 R R θ θ 0 0 θ2 2 R 2 R θ OTORO O I VI T 32

35 IX 8580 I O IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO TO TR O W OR PR. 4. IIO O OT I O. XI O 0.25 (0.00). T TI 2 42 P 0.25 (0.00) T 42 P 0.25 (0.00) T I IITR IX 8590 (IP) I O IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO TO TR O W OR PR. 4. IIO O OT I O. XI O 0.25 (0.00) T TI P 0.25 (0.00) T 56 P 0.25 (0.00) T I IITR OTORO O I VI T

36 , T IX (TQP32) I TI (0.008) 0.05 (0.002) V 0.20 (0.008) P,, TI (0.008) 0.05 (0.002) 0.20 (0.008) T TI 0.20 (0.008) TIO VIW ROTT 90 OWI TI T 0.0 (0.004) T TI X T R Q. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T, TO TRI T T. 5. IIO V TO TRI T TI. 6. IIO O OT I O PROTRIO. OW PROTRIO I 0.25 (0.00) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T IIO T XI TRI OITIO. R OT OT O T OWR RI OR T OOT. IITR I R R P Q R T V X.00 R R OTORO O I VI T 323

37 T IX (23-Pin ZIP) I 23. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. IIO R O OT I O OR PROTRIO. 4. IIO O OT I O OR PROTRIO. 5. O OR PROTRIO OT X 0.00 (0.250). 6. IIO O OT I R PROTRIO. OW PROTRIO (0.076) TOT I X O T IIO T XI TRI OITIO. R PI P PI 23 23X 0.00 (0.254) T Q Y 23X W T TI (0.60) T V I IITR P R V R R W Y OTORO O I VI T

38 T IX (TQP48) I 48 P 4X (0.008) T Z 9 TI Y T 36 V 2 25 V T,, Z TI Y 3 24 Z TOP & OTTO R 4X (0.008) T Z (0.00) (0.003) TI W X Q T ÇÇÇ ÇÇÇ ÉÉÉ (0.003) T Z TIO. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T T,, Z TO TRI T T. 5. IIO V TO TRI T TI. 6. IIO O OT I O PROTRIO. OW PROTRIO I (0.00) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. R PROTRIO OT T IIO TO X (0.04). 8. II OR PT TI (0.0003). 9. XT P O ORR I OPTIO. IITR I I I R 2 R P I 0.00 I Q 5 5 R V V W R R X.000 R R OTORO O I VI T 325

39 2T IX I V TRI 4. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. T OTOR OPTIO WITI IIO. 4. IIO V TI II OTI R OR TRI IIO O OT I O OR T PROTRIO. O T PROTRIO OT TO X (0.635) XI (0.254) T OPTIO R T I IITR R.295 R X 3.75 X R.270 R P R 5 R 5 R 0.6 R R I I V I I P R 2T IX (2P) I 0.00 (0.254) T OPTIO R V TRI 6 T. IIOI TORI PR I Y4.5, OTROI IIO: I. 3. T OTOR OPTIO WITI IIO. 4. IIO V TI II OTI R OR TRI IIO O OT I O OR T PROTRIO. O T PROTRIO OT TO X (0.635) XI. I IITR R.270 R P R 5 R 5 R 0.6 R R I I V I I R P 326 OTORO O I VI T

40 T, T IX (TOP20) I 0.5 (0.006) T 0.5 (0.006) T 2X /2 PI IT 0.00 (0.004) T TI X R 0.0 (0.004) T V V ÍÍÍÍ ÍÍÍÍ TIO TI 0.25 (0.00) TI W. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O, PROTRIO OR T RR. O OR T RR OT X 0.5 (0.006) PR I. 4. IIO O OT I ITR OR PROTRIO. ITR OR PROTRIO OT X 0.25 (0.00) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T IIO T XI TRI OITIO. 6. TRI R R OW OR RR OY. 7. IIO R TO TRI T T W. IITR I T IX (TOP6, TOP6) I O 0.5 (0.006) T 0.5 (0.006) T PI IT. 2X /2 6X R 0.0 (0.004) T V V ÇÇÇ ÇÇÇ ÉÉÉ TIO 0.25 (0.00) TI. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O. PROTRIO OR T RR. O OR T RR OT X 0.5 (0.006) PR I. 4. IIO O OT I ITR OR PROTRIO. ITR OR PROTRIO OT X 0.25 (0.00) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T IIO T XI TRI OITIO. 6. TRI R R OW OR RR OY. 7. IIO R TO TRI T T W. IITR I (0.004) T TI W TI OTORO O I VI T 327

41 T IX 9480 (TOP4) I O (0.006) T 0.5 (0.006) T 0.0 (0.004) T TI 2X /2 PI IT. 4 4X R 0.0 (0.004) T V (0.00) 7 V TI ÇÇÇ ÉÉ TIO TI W IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3 IIO O OT I O, PROTRIO OR T RR. O OR T RR OT X 0.5 (0.006) PR I. 4 IIO O OT I ITR OR PROTRIO. ITR OR PROTRIO OT X 0.25 (0.00) PR I. 5 IIO O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T IIO T XI TRI OITIO. 6 TRI R R OW OR RR OY. 7 IIO R TO TRI T T W. IITR I OTORO O I VI T

42 T IX 9480 I O (0.006) T 24X R 0.0 (0.004) T V 0.5 (0.006) T 2X /2 PI IT. 24 V 3 2. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. IIO O OT I O, PROTRIO OR T RR. O OR T RR OT X 0.5 (0.006) PR I. 4. IIO O OT I ITR OR PROTRIO. ITR OR PROTRIO OT X 0.25 (0.00) PR I. 5. IIO O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T IIO T XI TRI OITIO. 6. TRI R R OW OR RR OY. 7. IIO R TO TRI T T W. 0.0 (0.004) T TI W IITR I TI ÇÇÇ ÉÉÉ TIO TI 0.25 (0.00) OTORO O I VI T 329

43 T IX 9480 (TOP8) I O (0.006) T 0.5 (0.006) T 0.0 (0.004) T TI PI IT. 2X / x V R 0.0 (0.004) T V TI TI 0.25 (0.00) ÇÇÇ ÉÉ TIO W IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3 IIO O OT I O. PROTRIO OR T RR. O OR T RR OT X 0.5 (0.006) PR I. 4 IIO O OT I ITR OR PROTRIO. ITR OR PROTRIO OT X 0.25 (0.00) PR I. 5 IIO O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T IIO T XI TRI OITIO. 6 TRI R R OW OR RR OY. 7 IIO R TO TRI T T W. IITR I IX 9670 (I20) I O e 20 0 Z b 0.3 (0.005) (0.004) VIW P TI P Q c IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3 IIO O OT I O OR PROTRIO R R T T PRTI I. O OR PROTRIO OT X 0.5 (0.006) PR I. 4 TRI R R OW OR RR OY. 5 T WIT IIO (b) O OT I R PROTRIO. OW R PROTRIO 0.08 (0.003) TOT I X O T WIT IIO T XI TRI OITIO. R OT OT O T OWR RI OR T OOT. II P TW PROTRIO T TO 0.46 ( 0.08). IITR I b c e Q Z OTORO O I VI T

44 T IX 9760 (TQP20) I O 9 T 20 4X (0.008) T Z 20 6 TI Y 5. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T T,, Z TO TRI T T. 5. IIO V TO TRI T T. 6. IIO O OT I O PROTRIO. OW PROTRIO I (0.00) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. R PROTRIO OT T IIO TO X (0.04). 8. II OR PT TI (0.0003). 9. XT P O ORR I OPTIO. V V 5 4X (0.008) T Z 0 Z TI IITR I R 2 R P Q 5 5 R V V W R R X.000 R R TOP & OTTO (0.003) ÉÉÉÉ ÇÇÇÇ ÉÉÉÉ ÇÇÇÇ (0.003) T Z TIO R T,, Z W TI X Q (0.00) TI Y OTORO O I VI T 33

45 T IX 9770 I O X (0.008) T Z 24 9 TI Y. IIOI TORI PR I Y4.5, OTROI IIO: IITR. 3. T I OT T OTTO O I OIIT WIT T WR T XIT T PTI OY T T OTTO O T PRTI I. 4. T T,, Z TO TRI T T. 5. IIO V TO TRI T T. 6. IIO O OT I O PROTRIO. OW PROTRIO I (0.00) PR I. IIO O I O IT R TRI T T. 7. IIO O OT I R PROTRIO. R PROTRIO OT T IIO TO X (0.04). 8. II OR PT TI (0.0003). 9. XT P O ORR I OPTIO. V T V 6 4X (0.008) T Z 2 Z 8 3 IITR I R 2 R P Q 5 5 R V V W R R X.000 R R TI T,, Z TOP & OTTO (0.003) R ÉÉÉÉ ÇÇÇÇ ÉÉÉÉ ÇÇÇÇ P TI Y W TI X Q (0.00) (0.003) T Z TIO 332 OTORO O I VI T

46 IX 220 (OT23) I O IIO R I IITR. 2. ITRPRT IIO TOR PR Y4.5, T I TI e e 5X 0.0 IITR I I X e 0.95 e IX 230 (OT89) I O 2. IIO R I IITR. 2. ITRPRT IIO TORI PR Y4.5, T I TI. e e 0.0 2X 0.0 IITR I I X e.50 e OTORO O I VI T 333

MC1723C VOLTAGE REGULATOR

MC1723C VOLTAGE REGULATOR The 723 is a positive or negative voltage regulator designed to deliver load current to 50 mdc. Output current capability can be increased to several amperes through use of one or more external pass transistors.