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Op amps find extensive use in a wide variety of circuits, and their appropriate specification for a particular application requires knowledge of relevant data-sheet parameters. Data sheet specifications are divided into two general categories: dc parameters and ac parameters. The dc parameters represent internal errors that occur as a result of mismatches between devices and
components inside the op amp. These errors are always present from the time the power is turned on (i.e., before, during and after any input signal is applied), and they determine how precisely the output matches the ideal op-amp model. Thus the precision of the op amp is determined by the magnitude of the dc errors.
1 In t ro d u c t io n ..................................................................................................................... 3
2 In p u t O f fs e t V o l tag e D e f in e d ..................................................................................... 4
3 Cause of VI O ..................................................................................................................... 5
4 V I O a n d T e m p e r a tu r e D r i f t in th e M a jo r D e v ic e T y p e s ...................................... 5
4 . 1 B i p o l a r........................................................................................................................ 6
4 . 2 B i F E T ......................................................................................................................... 8
4 . 3 C M O S ........................................................................................................................ 9
5 M a n ufa cturer Me as u rem e nt, Trim, an d S p e cific a tio n of VIO ........................... 9
5 . 1 M e a s u r e m e n t........................................................................................................... 9
5 . 2 T r im...........................................................................................................................1 0
5 . 3 S p e c i f i c a t io n s ........................................................................................................1 0
6 Impact of VI O on Circ uit D e sign an d M e th o d s o f Cor r e c tion ........................ 1 4
6 . 1 A C C o u p l i n g ...........................................................................................................1 5
6.2 D C F e e d b a c k.........................................................................................................1 7
6 . 3 I n t e r n a l C a l ib r a t io n ...............................................................................................1 8
6 . 4 E x t e r n a l C a l ib r a t io n .............................................................................................1 9
7 S u m m a r y ........................................................................................................................ 2 1
R e f e r e n c e s........................................................................................................................... 2 2
Figures
1 I d e a l O p - A m p M o d e l a n d M o d e l P a r am e t e r s ....................................................... 3
2 N o n i d e a l O p - A m p M o d e l ............................................................................................ 4
3 D is t r ib u tio n o f V I O fo r th e T L V 2 7 2 1 .......................................................................... 4
4 S i m p l if ie d D i f f e re nt i a l-P a i r A m p l if ie r . Q 1 a nd Q 2 A r e B J T, F E T o r M O S . ... 5
5 B ip o la r T ra n s is to r D i f fe re n t ial-P a i r C irc u i t . (a) B a s ic C ircu i t a n d (b)
G e n e r a l C i r c u it U se d to C a lc u l a t e VI O..................................................................... 6
6 S im p l i f ie d S e r v o - L o o p T e s t C i r c u i t ........................................................................ 1 0
7 G r a p h o f V I O D r if t O v e r 0 –7 0°C .......................................................................... 1 3 1 2
8 V I O v s V I C f o r ( a ) T L C 0 7 1 a n d (b ) T L C 0 8 1 O p A m p s .................................. 1 4 1 3
SLOA059
2 DC Parameters: Input Offset Voltage (VIO)
9 V I O C h a n g e s W ith C o m m o n M o d e In pu t V o lta g e (VIC) f o r (a) the T L V 2 4 7 x
a n d ( b ) t h e T L V 2 7 3 1 ...................................................................................................1 4
1 0 In v e r t in g O p - A m p C i r c u it W i th VI O I n c lu d e d ........................................................1 5
1 1 A C C o u p l e d I n v e r ti n g A m p l i f ie r ...............................................................................1 6
1 2 G e n e ra l F o rm o f DC F e e d b a c k L o o p ....................................................................1 7
1 3 S im p l ifie d B lo c k D ia g r a m o f th e T L C 26 5 4 Ch o p p e r -St a b il iz e d A m p l if ie r ..1 8
1 4 B l o c k D i a g r a m o f C h a n n e l O n e o f t h e T L C 4 5 0 2 ...............................................1 9
1 5 T y p i c a l N u l l C o n f ig u r a t i o n o f a n A m p l if i e r............................................................2 0
1 6 VIO A d ju s tm e n t W ith a P o te n tio m e te r a n d L o w T e m p e ra tu r e C o e ff icie n t
R e s i s t o r...........................................................................................................................2 0
Tables
1 R a n g e o f I n p u t O f fs e t V o l t a g e a n d D r if t P e r D e v i c e P r o c e s s .......................... 6
2 Example of VI O S pe c if ic a t io n s T a k e n F r o m T L E 2 0 2 1 D a ta S h e e t
( S L O S 1 9 1 ) .....................................................................................................................1 1
3 C o n v e r t e r R e s o l u t io n ..................................................................................................1 7
components inside the op amp. These errors are always present from the time the power is turned on (i.e., before, during and after any input signal is applied), and they determine how precisely the output matches the ideal op-amp model. Thus the precision of the op amp is determined by the magnitude of the dc errors.
1 In t ro d u c t io n ..................................................................................................................... 3
2 In p u t O f fs e t V o l tag e D e f in e d ..................................................................................... 4
3 Cause of VI O ..................................................................................................................... 5
4 V I O a n d T e m p e r a tu r e D r i f t in th e M a jo r D e v ic e T y p e s ...................................... 5
4 . 1 B i p o l a r........................................................................................................................ 6
4 . 2 B i F E T ......................................................................................................................... 8
4 . 3 C M O S ........................................................................................................................ 9
5 M a n ufa cturer Me as u rem e nt, Trim, an d S p e cific a tio n of VIO ........................... 9
5 . 1 M e a s u r e m e n t........................................................................................................... 9
5 . 2 T r im...........................................................................................................................1 0
5 . 3 S p e c i f i c a t io n s ........................................................................................................1 0
6 Impact of VI O on Circ uit D e sign an d M e th o d s o f Cor r e c tion ........................ 1 4
6 . 1 A C C o u p l i n g ...........................................................................................................1 5
6.2 D C F e e d b a c k.........................................................................................................1 7
6 . 3 I n t e r n a l C a l ib r a t io n ...............................................................................................1 8
6 . 4 E x t e r n a l C a l ib r a t io n .............................................................................................1 9
7 S u m m a r y ........................................................................................................................ 2 1
R e f e r e n c e s........................................................................................................................... 2 2
Figures
1 I d e a l O p - A m p M o d e l a n d M o d e l P a r am e t e r s ....................................................... 3
2 N o n i d e a l O p - A m p M o d e l ............................................................................................ 4
3 D is t r ib u tio n o f V I O fo r th e T L V 2 7 2 1 .......................................................................... 4
4 S i m p l if ie d D i f f e re nt i a l-P a i r A m p l if ie r . Q 1 a nd Q 2 A r e B J T, F E T o r M O S . ... 5
5 B ip o la r T ra n s is to r D i f fe re n t ial-P a i r C irc u i t . (a) B a s ic C ircu i t a n d (b)
G e n e r a l C i r c u it U se d to C a lc u l a t e VI O..................................................................... 6
6 S im p l i f ie d S e r v o - L o o p T e s t C i r c u i t ........................................................................ 1 0
7 G r a p h o f V I O D r if t O v e r 0 –7 0°C .......................................................................... 1 3 1 2
8 V I O v s V I C f o r ( a ) T L C 0 7 1 a n d (b ) T L C 0 8 1 O p A m p s .................................. 1 4 1 3
SLOA059
2 DC Parameters: Input Offset Voltage (VIO)
9 V I O C h a n g e s W ith C o m m o n M o d e In pu t V o lta g e (VIC) f o r (a) the T L V 2 4 7 x
a n d ( b ) t h e T L V 2 7 3 1 ...................................................................................................1 4
1 0 In v e r t in g O p - A m p C i r c u it W i th VI O I n c lu d e d ........................................................1 5
1 1 A C C o u p l e d I n v e r ti n g A m p l i f ie r ...............................................................................1 6
1 2 G e n e ra l F o rm o f DC F e e d b a c k L o o p ....................................................................1 7
1 3 S im p l ifie d B lo c k D ia g r a m o f th e T L C 26 5 4 Ch o p p e r -St a b il iz e d A m p l if ie r ..1 8
1 4 B l o c k D i a g r a m o f C h a n n e l O n e o f t h e T L C 4 5 0 2 ...............................................1 9
1 5 T y p i c a l N u l l C o n f ig u r a t i o n o f a n A m p l if i e r............................................................2 0
1 6 VIO A d ju s tm e n t W ith a P o te n tio m e te r a n d L o w T e m p e ra tu r e C o e ff icie n t
R e s i s t o r...........................................................................................................................2 0
Tables
1 R a n g e o f I n p u t O f fs e t V o l t a g e a n d D r if t P e r D e v i c e P r o c e s s .......................... 6
2 Example of VI O S pe c if ic a t io n s T a k e n F r o m T L E 2 0 2 1 D a ta S h e e t
( S L O S 1 9 1 ) .....................................................................................................................1 1
3 C o n v e r t e r R e s o l u t io n ..................................................................................................1 7
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