高输出电流高驱动能力运放IC MC33076(可编辑)高输出电流高驱动能力运放IC MC33076(可编辑)
高输出电流高驱动能力运放IC MC33076
The MC33076 operational amplifier employs bipolar technology
with innovative high performance concepts for audio and industrial httponsemicom
applications This device uses high frequency PNP input transistors to...
高输出电流高驱动能力运放IC MC33076(可编辑)
高输出电流高驱动能力运放IC MC33076
The MC33076 operational amplifier employs bipolar technology
with innovative high performance concepts for audio and industrial httponsemicom
applications This device uses high frequency PNP input transistors to
improve frequency response In addition the amplifier provides high MARKING
output current drive capability while minimizing the drain
DIAGRAMS
current The all NPN output stage exhibits no deadband crossover 8
distortion large output voltage swing excellent phase and
gain
MC33076P1
margins low open loop high frequency output impedance and PDIP–8 AWL
symmetrical source and sink AC frequency performance P1 SUFFIX YYWW
The MC33076 is tested over the automotive temperature range and 8 CASE 626
1
is available in an 8–pin SOIC package D suffix and in the standard
1
8 pin DIP package for high power applications 8
100 Output Drive Capability
SO–8 33076
Large Output Voltage Swing 8 D SUFFIX ALYW
Low Total Harmonic Distortion CASE 751
1
1
High Gain Bandwidth 74 MHz
High Slew Rate 26 Vμs
A Assembly Location
Dual Supply Operation ?20 V to ? 18 V WL L Wafer Lot
High Output Current ISC 250 mA typ YY Y Year
Similar Performance to MC33178 WW W Work Week
PIN CONNECTIONS
ORDERING INFORMATION
Device Package Shipping
MC33076D SO–8 98 UnitsRail
MC33076DR2 SO–8 2500 Tape Reel
MC33076P1 PDIP–8 50 UnitsRail
Figure 1 Equivalent Circuit Schematic
Each Amplifier
Semiconductor Components Industries LLC 2001 1 Publication Order Number
February 2001 – Rev 1
MC33076D
MC33076
IMUM RATINGS
Rating Symbol Value Unit
Power Supply Voltage Note 2 VCC to 36 V
VEE
Input Differential Voltage Range VIDR Note 1 V
Input Voltage Range VIR Note 1 V
Output Short Circuit Duration Note 2 tSC 50 sec
imum Junction Temperature TJ 150 ?C
Storage Temperature
Tstg –60 to 150 ?C
imum Power Dissipation
PD Note 2 mW
1 Either or both input voltages should not exceed VCC or VEE
2 Power dissipation must be considered to ensure imum junction temperature TJ is not exceeded see power dissipation
performance characteristic Figure 2 See applications section for further information
DC ELECTRICAL CHARACTERICISTICS V 15 V V –15 V T 25?C unless otherwise noted
CC EE A
Characteristics Figure Symbol Min Typ Unit
Input Offset Voltage R 50 V 0 V
3 V mV
S CM IO
VS ?25 V to ? 15 V
TA 25?C – 05 40
TA –40? to 85?C – 05 50
Input Offset Voltage Temperature Coefficient VIOT μV?C
RS 50 VCM 0 V
TA –40? to 85?C – 20 –
Input Bias Current VCM 0 V
4 5 IIB nA
TA 25?C – 100 500
TA –40? to 85?C – – 600
Input Offset Current VCM 0 V IIO nA
TA 25?C – 50 70
TA –40? to 85?C – – 100
Common Mode Input Voltage Range
6 VICR –13 –14 V
14 13
Large Signal Voltage Gain V –10 V to 10 V
7 A kVV
O VOL
T 25?C
A
RL 100 25 – –
RL 600 50 200 –
T –40? to 85?C
A
RL 600 25 – –
Output Voltage Swing VID ? 10 V 8 9 10 V
VCC 15 V VEE –15 V
RL 100 VO 10 117 –
RL 100 VO– – –117 –10
RL 600 VO 13 138 –
RL 600 VO– – –138 –13
VCC 25 V VEE –25 V
RL 100 VO 12 166 –
RL 100 VO– – –174 –12
Common Mode Rejection Vin ? 13 V 11 CMR 80 116 – dB
Power Supply Rejection 12 PSR dB
VCCVEE 15 V–15 V 50 V–15 V 15 V–50 V 80 120 –
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MC33076
DC ELECTRICAL CHARACTERICISTICS V 15 V V –15 V T 25?C unless otherwise noted
CC EE A
Characteristics Figure Symbol Min Typ Unit
Output Short Circuit Current VID ? 10 V Output to Gnd 13 14 ISC mA
VCC 15 V VEE –15 V
Source
190 250 –
Sink
– –280 –215
VCC 25 V VEE –25 V
Source 63 94 –
Sink – –80 –46
Power Supply Current per Amplifier VO 0 V
15 ID mA
VS ?25 V to ? 15 V
TA 25?C – 22 28
TA –40? to 85?C – – 33
AC ELECTRICAL CHARACTERICISTICS V 15 V V
–15 V T 25?C unless otherwise noted
CC EE A
Characteristics Figure Symbol Min Typ Unit
Slew Rate V –10 V to 10 V R 100 C 100 pF A 10 16 SR 12 26 – Vμs
in L L
V
Gain Bandwidth Product f 20 kHz 17 GBW 40 74 – MHz
Unity Gain Bandwidth Open Loop R 600 C 0 pF – BW – 35 – MHz
L L
Gain Margin R 600 C 0 pF
20 21 A – 15 – dB
L L m
Phase Margin R 600 C 0 pF 20 21 – 52 – Deg
L L m
Channel Separation f 100 Hz to 20 kHz 22 CS – –120 – dB
Power Bandwidth V 20 V R 600 THD ? 1
– BW – 32 – kHz
O pp L p
Total Harmonic Distortion R 600 V 20 V A 10 23 THD
L O pp V
f 10 kHz – 00027 –
f 10 kHz – 0011 –
f 20 kHz – 0022 –
Open Loop Output Impedance V 0 V f 25 MHz A 10
24 Z – 75 –
O V O
Differential Input Resistance VCM 0 V
– Rin – 200 – k
Differential Input Capacitance VCM 0 V
– Cin – 10 – pF
Equivalent Input Noise Voltage R 100
25 e nV?Hz
S n
f 10 Hz – 75
f 10 kHz – 50 –
Equivalent Input Noise Current
– in pA?Hz
f 10 Hz – 033 –
f 10 kHz – 015 –
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MC33076
?
?
?
Figure 2 imum Power Dissipation Figure 3 Distribution of Input
versus Temperature Offset Voltage
?
?
Figure 4 Input Bias Current versus Figure 5 Input Bias Current
Common Mode Voltage versus Temperature
15 V
? ?
Figure 6 Input Common Mode Voltage Figure 7 Open Loop Voltage Gain
Range versus Temperature versus
Temperature
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MC33076
?
?
?
?
Figure 8 Output Voltage Swing Figure 9 imum Peak–to–Peak Output
versus Supply Voltage Voltage Swing versus Load Resistance
? ?
? ??
Figure 10 Output Voltage Figure 11 Common Mode Rejection
versus Frequency versus Frequency Over Temperature
?
??
?
Figure 12 Power Supply Rejection Figure 13 Output Short Circuit Current
versus Frequency Over Temperature versus Output
Voltage
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MC33076
1?
?
?
?
?
Figure 14 Output Short Circuit Current Figure 15 Supply Current versus
versus Temperature Supply Voltage with No Load
μ
1
15
1
15
? ?
Figure 16 Slew Rate Figure 17 Gain Bandwidth Product
versus Temperature versus Temperature
?
?
?
?
Figure 18 Voltage Gain and Phase Figure 19 Voltage Gain and Phase
versus Frequency versus Frequency
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MC33076
1 1
15
15
?
Figure 20 Phase Margin and Gain Margin Figure 21 Open Loop Gain Margin and Phase
versus Differential Source Resistance Margin versus Output Load Capacitance
1
15
?
1
15
?
Figure 22 Channel Separation Figure 23 Total Harmonic Distortion
versus Frequency versus Frequency
?
1 1
15 15
?
?
Figure 24 Output Impedance Figure 25 Input Referred Noise Voltage
versus Frequency versus Frequency
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MC33076
?
Figure 26 Percent Overshoot Figure 27 PC Board Heatsink Example
versus Load Capacitance
APPLICATIONS INFORMATION
The MC33076 dual operational amplifier is available in 52?CW typically in still air The junction–to–ambient
the standard 8–pin plastic dual–in–line DIP and surface thermal
resistance RθJA can be decreased further by using
mount packages and also in a 16–pin batwing power a
copper padb on the printed circuit board as shown in
package To enhance the power dissipation capability of the Figure 27 to draw the heat away from the package Care
power package Pins 4 5 12 and 13 are tied together on the must be
taken not to exceed the imum junction
leadframe giving it an ambient thermal resistance of temperature or damage to the device may occur
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MC33076
PACKAGE DIMENSIONS
PDIP–8
P1 SUFFIX
CASE 626–05
ISSUE L
–B–
F
NOTE 2 –A–
L
C
J
–T–
N
M
D K
H G
SO–8
D SUFFIX
CASE 751–07
ISSUE W
–X–
A
B S
–Y– K
G
C N X 45
–Z–
H D M J
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MC33076
Notes
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MC33076
Notes
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MC33076
ON Semiconductor and are trademarks of Semiconductor Components Industries LLC SCILLC SCILLC reserves the right to make changes
without further notice to any products herein SCILLC makes no warranty representation or guarantee regarding the suitability of its products for any particular
purpose nor does SCILLC assume any liability arising out of the application or use of any product or circuit and specifically disclaims any and all liability
including without limitation special consequential or incidental
damages Typical parameters which may be provided in SCILLC data sheets andor
specifications can and do vary in different applications and actual performance may vary over time All operating parameters including Typicals must be
validated for each customer application by customers technical experts SCILLC does not convey any license under its patent rights nor the rights of others
SCILLC products are not designed intended or authorized for use as components in systems intended for surgical implant into the body or other applications
intended to support or sustain life or for any other application in which the failure of the SCILLC product could create a situation where personal injury or
death may occur Should Buyer purchase or use SCILLC products for any such unintended or unauthorized application Buyer shall indemnify and hold
SCILLC and its officers employees subsidiaries affiliates and
distributors harmless against all claims costs damages and expenses and
reasonable
attorney fees arising out of directly or indirectly any claim of
personal injury or death associated with such unintended or unauthorized use even if such claim
alleges that SCILLC was negligent regarding the design or
manufacture of the part SCILLC is an Equal OpportunityAffirmative Action Employer
PUBLICATION ORDERING INFORMATION
NORTH AMERICA Literature Fulfillment CENTRALSOUTH AMERICA
Literature Distribution Center for ON Semiconductor Spanish Phone 303–308–7143 Mon–Fri 800am to 500pm MST
PO Box 5163 Denver Colorado 80217 USA
Email ONlit–spanishhibbertcocom
Phone 303–675–2175 or 800–344–3860 Toll Free USACanada Toll–Free from Mexico Dial 01–800–288–2872 for Access –
Fax 303–675–2176 or 800–344–3867 Toll Free USACanada
then Dial 866–297–9322
Email ONlithibbertcocom
ASIAPACIFIC LDC for ON Semiconductor – Asia Support
Fax Response Line 303–675–2167 or 800–344–3810 Toll Free
USACanada
Phone 303–675–2121 Tue–Fri 900am to 100pm Hong Kong Time
N American Technical Support 800–282–9855 Toll Free USACanada Toll Free from Hong Kong Singapore
001–800–4422–3781
EUROPE LDC for ON Semiconductor – European Support Email ONlit–asiahibbertcocom
German Phone 1 303–308–7140 Mon–Fri 230pm to 700pm CET
Email ONlit–germanhibbertcocom JAPAN ON Semiconductor Japan Customer Focus Center
French Phone 1 303–308–7141 Mon–Fri 200pm to 700pm CET 4–32–1 Nishi–Gotanda Shinagawa–ku Tokyo Japan 141–0031
Email ONlit–frenchhibbertcocom Phone 81–3–5740–2700
English Phone 1 303–308–7142 Mon–Fri 1200pm to 500pm GMT Email r14525onsemicom
Email ONlithibbertcocom ON Semiconductor Website httponsemicom
EUROPEAN TOLL–FREE ACCESS 00–800–4422–3781 For additional information please contact your local
Available from Germany France Italy UK Ireland Sales Representative
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12
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