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LM258WYPT [STMICROELECTRONICS]

Low power dual operational amplifiers; 低功耗双运算放大器
LM258WYPT
型号: LM258WYPT
厂家: ST    ST
描述:

Low power dual operational amplifiers
低功耗双运算放大器

运算放大器
文件: 总18页 (文件大小:326K)
中文:  中文翻译
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LM158W-LM258W-LM358W  
Low power dual operational amplifiers  
Features  
Internally frequency compensated  
Large DC voltage gain: 100 dB  
N
DIP-8  
(Plastic package)  
Wide bandwidth (unity gain): 1.1 MHz  
(temperature compensated)  
Very low supply current per operator  
essentially independent of supply voltage  
Low input bias current: 20 nA  
D & S  
SO-8 & miniSO-8  
(Plastic micropackage)  
(temperature compensated)  
Low input offset voltage: 2 mV  
Low input offset current: 2 nA  
Input common-mode voltage range includes  
ground  
P
Differential input voltage range equal to the  
TSSOP8  
(Thin shrink small outline package)  
power supply voltage  
+
Large output voltage swing 0 V to V  
ESD internal protection: 1.5 kV  
- 1.5 V  
CC  
Pin connections  
(top view)  
Description  
1
2
3
4
8
7
6
5
These circuits consist of two independent, high-  
gain, internally frequency-compensated which  
were designed specifically to operate from a  
single power supply over a wide range of  
voltages. The low power supply drain is  
independent of the magnitude of the power supply  
voltage.  
-
+
-
+
Application areas include transducer amplifiers,  
DC gain blocks and all the conventional op-amp  
circuits which now can be more easily  
1 - Output 1  
2 - Inverting input  
3 - Non-inverting input  
implemented in single power supply systems. For  
example, these circuits can be directly supplied  
with the standard +5 V which is used in logic  
systems and will easily provide the required  
interface electronics without requiring any  
additional power supply.  
-
4 - VCC  
5 - Non-inverting input 2  
6 - Inverting input 2  
7 - Output 2  
+
8 - VCC  
In the linear mode the input common-mode  
voltage range includes ground and the output  
voltage can also swing to ground, even though  
operated from only a single power supply voltage.  
February 2008  
Rev 7  
1/18  
www.st.com  
18  
Schematic diagram  
LM158W-LM258W-LM358W  
1
Schematic diagram  
Figure 1.  
Schematic diagram (1/2 LM158W)  
2/18  
LM158W-LM258W-LM358W  
Absolute maximum ratings and operating conditions  
2
Absolute maximum ratings and operating conditions  
Table 1.  
Symbol  
Absolute maximum ratings  
Parameter  
LM158W/AW LM258W/AW LM358W/AW  
Unit  
+
VCC  
Supply voltage  
Input voltage  
+32  
-0.3 to VCC+ +0.3  
-0.3 to VCC+ +0.3  
Infinite  
V
V
V
Vin  
Vid  
Differential input voltage  
Output short-circuit duration (1)  
Input current (2)  
Iin  
Toper  
Tstg  
Tj  
50  
mA  
°C  
°C  
°C  
Operating free-air temperature range  
Storage temperature range  
Maximum junction temperature  
-55 to +125  
-40 to +105  
-65 to +150  
150  
0 to +70  
Thermal resistance junction to ambient(3)  
125  
190  
120  
85  
SO-8  
Rthja  
°C/W  
°C/W  
MiniSO-8  
TSSOP8  
DIP-8  
Thermal resistance junction to case(3)  
40  
39  
37  
41  
SO-8  
Rthjc  
MiniSO-8  
TSSOP8  
DIP-8  
HBM: human body model(4)  
MM: machine model(5)  
1.5  
200  
1.5  
kV  
V
ESD  
CDM: charged device model(6)  
kV  
1. Short-circuits from the output to VCC can cause excessive heating if VCC > 15V. The maximum output current is  
approximately 40 mA independent of the magnitude of VCC. Destructive dissipation can result from simultaneous short-  
circuits on all amplifiers.  
2. This input current only exists when the voltage at any of the input leads is driven negative. It is due to the collector-base  
junction of the input PNP transistor becoming forward biased and thereby acting as input diode clamps. In addition to this  
diode action, there is also NPN parasitic action on the IC chip. This transistor action can cause the output voltages of the  
Op-amps to go to the VCC voltage level (or to ground for a large overdrive) for the time during which an input is driven  
negative. This is not destructive and normal output will be restored for input voltage higher than -0.3 V.  
3. Short-circuits can cause excessive heating and destructive dissipation. Rth are typical values.  
4. Human body model: 100 pF discharged through a 1.5 kΩ resistor between two pins of the device, done for all couples of pin  
combinations with other pins floating.  
5. Machine model: a 200 pF cap is charged to the specified voltage, then discharged directly between two pins of the device  
with no external series resistor (internal resistor < 5 Ω), done for all couples of pin combinations with other pins floating.  
6. Charged device model: all pins plus package are charged together to the specified voltage and then discharged directly to  
the ground.  
3/18  
Absolute maximum ratings and operating conditions  
LM158W-LM258W-LM358W  
Table 2.  
Symbol  
Operating conditions  
Parameter  
Value  
Unit  
+
VCC  
Supply voltage  
3 to 30  
V
V
Vicm  
Common mode input voltage range  
VDD -0.3 to VCC -1.5  
Operating free air temperature range  
-55 to +125  
-40 to +105  
0 to +70  
LM158W  
LM258W  
LM358W  
Toper  
°C  
4/18  
LM158W-LM258W-LM358W  
Electrical characteristics  
3
Electrical characteristics  
+
-
Table 3.  
Symbol  
V
= +5 V, V = Ground, V = 1.4 V, T = +25°C (unless otherwise specified)  
amb  
CC  
CC  
o
Parameter  
Min.  
Typ.  
Max.  
Unit  
Input offset voltage (1)  
LM158AW  
LM258AW, LM358AW  
LM158W, LM258W  
LM358W  
1
1
2
2
2
3
5
7
Vio  
mV  
Tmin Tamb Tmax  
LM158AW, LM258AW, LM358AW  
LM158W, LM258W  
LM358W  
4
7
9
Input offset voltage drift  
DVio  
µV/°C  
nA  
LM158AW, LM258AW, LM358AW  
LM158W, LM258W, LM358W  
7
7
15  
30  
Input offset current  
2
2
10  
30  
LM158AW, LM258AW, LM358AW  
LM158W, LM258W, LM358W  
Iio  
DIio  
Iib  
Tmin Tamb Tmax  
LM158AW, LM258AW, LM358AW  
LM158W, LM258W, LM358W  
30  
40  
Input offset current drift  
pA/°C  
nA  
LM158AW, LM258AW, LM358AW  
LM158W, LM258W, LM358W  
10  
10  
200  
300  
Input bias current (2)  
LM158AW, LM258AW, LM358AW  
LM158W, LM258W, LM358W  
20  
20  
50  
150  
Tmin Tamb Tmax  
LM158AW, LM258AW, LM358AW  
LM158W, LM258W, LM358W  
100  
200  
Large signal voltage gain  
Avd  
SVR  
ICC  
VCC+ = +15 V, RL = 2 kΩ, Vo = 1.4 V to 11.4 V  
Tmin Tamb Tmax  
50  
25  
100  
100  
0.7  
V/mV  
dB  
Supply voltage rejection ratio  
Rs 10 kΩ, VCC+ = 5 V to 30 V  
Tmin Tamb Tmax  
65  
65  
Supply current, all amp, no load  
Tmin Tamb Tmax, VCC+ = +5 V  
Tmin Tamb Tmax, VCC+ = +30 V  
1.2  
2
mA  
Input common mode voltage range  
VCC+ = +30 V (3)  
Vicm  
V
0
0
VCC+ -1.5  
VCC+ -2  
Tamb = +25° C  
Tmin Tamb Tmax  
5/18  
Electrical characteristics  
LM158W-LM258W-LM358W  
+
-
Table 3.  
Symbol  
V
= +5 V, V = Ground, V = 1.4 V, T = +25°C (unless otherwise specified)  
amb  
CC  
CC  
o
Parameter  
Min.  
Typ.  
Max.  
Unit  
Common mode rejection ratio  
Rs 10kΩ  
Tmin Tamb Tmax  
CMR  
Isource  
Isink  
70  
60  
85  
dB  
Output current source  
VCC+ = +15 V, Vo = +2 V, Vid = +1 V  
20  
40  
60  
mA  
Output sink current  
VCC+ = +15V, Vo = +2V, Vid = -1 V  
10  
12  
20  
50  
mA  
µA  
VCC+ = +15V, Vo = +0.2V, Vid = -1 V  
High level output voltage  
RL = 2 kΩ, VCC+ = 30 V  
Tmin Tamb Tmax  
26  
26  
27  
27  
27  
28  
VOH  
V
RL = 10 kΩ, VCC+ = 30 V  
Tmin Tamb Tmax  
Low level output voltage  
RL = 10 kΩ  
Tmin Tamb Tmax  
VOL  
5
20  
20  
mV  
V/µs  
MHz  
%
Slew rate  
VCC+ = 15 V, Vi = 0.5 to 3 V, RL = 2 kΩ,  
SR  
0.3  
0.7  
0.6  
1.1  
0.02  
CL = 100 pF, unity gain  
Gain bandwidth product  
VCC+ = 30 V, f =100 kHz, Vin =10 mV, RL=2 kΩ,  
GBP  
THD  
CL = 100 pF  
Total harmonic distortion  
f = 1 kHz, Av = 20 dB, RL = 2 kΩ, Vo = 2 Vpp  
CL = 100 pF, VO = 2 Vpp  
,
Equivalent input noise voltage  
f = 1 kHz, Rs = 100 Ω, VCC+ = 30 V  
nV  
en  
-----------  
55  
Hz  
Channel separation (4)  
Vo1/Vo2  
1 kHz f 20 kHz  
120  
dB  
1. Vo = 1.4 V, Rs = 0 Ω, 5 V < VCC+ < 30 V, 0 < Vic < VCC+ - 1.5 V  
2. The direction of the input current is out of the IC. This current is essentially constant, independent of the state of the output  
so there is no change in the load on the input lines.  
3. The input common-mode voltage of either input signal voltage should not be allowed to go negative by more than 0.3 V.  
The upper end of the common-mode voltage range is VCC+ - 1.5 V, but either or both inputs can go to +32 V without  
damage.  
4. Due to the proximity of external components ensure that there is no coupling originating via stray capacitance between  
these external parts. Typically, this can be detected at higher frequencies because then this type of capacitance increases.  
6/18  
LM158W-LM258W-LM358W  
Electrical characteristics  
Figure 2. Open loop frequency response  
Figure 3. Large signal frequency response  
(NOTE 3)  
OPEN LOOP FREQUENCY RESPONSE  
140  
LARGE SIGNAL FREQUENCY RESPONSE  
20  
10M  
100k  
W
W
0.1  
F
120  
100  
m
1k  
W
+15V  
-
V
-
CC  
VO  
V
V
I
V
I
15  
10  
O
V
/2  
CC  
2k  
+
+
W
+7V  
80  
60  
40  
V
CC  
-55°C  
= 30V &  
T
amb  
+125°C  
5
0
20  
0
V
= +10 to + 15V &  
CC  
T
amb  
+125°C  
-55°C  
1.0 10  
100  
1k  
10k 100k 1M 10M  
1k  
10k  
100k  
1M  
FREQUENCY (Hz)  
FREQUENCY (Hz)  
Figure 4. Voltage follower pulse response  
Figure 5. Voltage follower pulse response  
VOLTAGE FOLLOWER PULSSE RESPONSE  
VOLAGE FOLLOWER PULSE RESPONSE  
4
(SMALL SIGNAL)  
500  
RL 2 k  
W
3
VCC = +15V  
+
450  
e
2
1
0
3
2
1
O
e
l
-
50pF  
400  
350  
300  
250  
Input  
Output  
T
V
= +25°C  
= 30 V  
amb  
CC  
0
10  
20  
30  
40  
0
1
2
3
4
5
6
7
8
TIME ( s)  
TIME ( s)  
m
m
Figure 6. Input current  
Figure 7. Output characteristics  
INPUT CURRENT (Note 1)  
OUTPUT CHARACTERISTICS  
10  
90  
80  
70  
60  
VCC = +5V  
VCC = +15V  
VCC = +30V  
V = 0 V  
I
V
V
= +30 V  
= +15 V  
CC  
1
50  
40  
v
cc  
CC  
v
/2  
cc  
-
30  
20  
10  
0
0.1  
I
O
V
= +5 V  
V
O
+
CC  
T
= +25°C  
10  
amb  
0.01  
0,001  
0,01  
0,1  
1
100  
-55 -35 -15  
5
25 45 65 85 105 125  
TEMPERATURE (°C)  
OUTPUT SINK CURRENT (mA)  
7/18  
Electrical characteristics  
LM158W-LM258W-LM358W  
Figure 8. Output characteristics  
Figure 9. Current limiting  
CURRENT LIMITING (Note 1)  
OUTPUT CHARACTERISTICS  
90  
80  
70  
60  
8
V
CC  
-
I
7
O
+
-
V
V
/2  
6
O
CC  
+
5
I
50  
40  
O
4
30  
20  
10  
0
Independent of V  
CC  
3
2
1
T
= +25°C  
amb  
-55 -35 -15  
5
25 45 65 85 105 125  
0,01  
0,1  
1
10  
100  
0,001  
OUTPUT SOURCE CURRENT (mA)  
TEMPERATURE (°C)  
Figure 10. Input voltage range  
Figure 11. Positive supply voltage  
INPUT VOLTAGE RANGE  
160  
15  
10  
5
W
R L = 20k  
120  
W
R L = 2k  
Négative  
80  
40  
Positive  
0
10  
20  
30  
40  
0
5
10  
15  
POSITIVE SUPPLY VOLTAGE (V)  
POWER SUPPLY VOLTAGE (±V)  
Figure 12. Input voltage range  
Figure 13. Supply current  
SUPPLY CURRENT  
160  
4
3
2
1
W
R L = 20k  
V
CC  
120  
80  
I
D
mA  
-
W
R L = 2k  
+
40  
T
= 0°C to +125°C  
amb  
T
= -55°C  
amb  
0
10  
20  
30  
0
10  
20  
30  
POSITIVE SUPPLY VOLTAGE (V)  
POSITIVE SUPPLY VOLTAGE (V)  
8/18  
LM158W-LM258W-LM358W  
Electrical characteristics  
Figure 14. Input current  
Figure 15. Gain bandwidth product  
100  
1.5  
1.35  
1.2  
75  
50  
25  
1.05  
0.9  
VCC  
=
15V  
0.75  
0.6  
0.45  
0.3  
Tamb= +25°C  
0.15  
0
-55-35-15 5 25 45 65 85 105 125  
0
10  
20  
30  
TEMPERATURE (°C)  
POSITIVE SUPPLY VOLTAGE (V)  
Figure 16. Power supply rejection ratio  
Figure 17. Common mode rejection ratio  
115  
110  
105  
100  
95  
115  
110  
SVR  
105  
100  
95  
90  
85  
80  
75  
70  
65  
90  
85  
80  
75  
70  
65  
-55-35-15 5 25 45 65 85 105 125  
60  
-55-35-15 5 25 45 65 85 105 125  
60  
TEMPERATURE (°C)  
TEMPERATURE (°C)  
Figure 18. Phase margin vs. capacitive load  
Phase Margin at Vcc=15V and Vicm=7.5V  
Vs. Iout and Capacitive load value  
9/18  
Typical applications  
LM158W-LM258W-LM358W  
4
Typical applications  
Single supply voltage V = +5 V  
CC  
DC  
Figure 19. AC coupled inverting amplifier  
Figure 20. Non-inverting DC amplifier  
Rf  
100k  
R2  
R1  
W
Rf  
A
V= 1 +  
A = -  
V
R1  
10k  
W
R1  
(as shown A = -10)  
A
(As shown V = 101)  
V
CI  
W
10k  
eO  
+5V  
Co  
1/2  
LM158  
1/2  
LM158  
2VPP  
0
eo  
R
B
W
R
L
W
6.2k  
10k  
eI  
R2  
100k  
R3  
W
100k  
~
V
W
R2  
CC  
1M  
W
R1  
W
10k  
C1  
m
10  
F
0
eI  
(mV)  
Figure 21. AC coupled non-inverting amplifier Figure 22. DC summing amplifier  
e 1  
W
R1  
100k  
R2  
1M  
100k  
W
W
R2  
R1  
A
= 1 +  
V
(as shown A = 11)  
V
C1  
0.1 F  
m
eO  
1/2  
LM158  
Co  
100k  
W
1/2  
LM158  
2VPP  
0
eo  
CI  
e 2  
e 3  
W
W
100k  
R
B
W
R
L
10k  
6.2k  
100k  
W
R3  
1M  
eI  
~
W
100k  
W
R4  
100k  
W
e 4  
100k  
W
V
CC  
C2  
R5  
W
100k  
e
= e + e - e - e  
1 2 3 4  
m
o
10 F  
where (e1 + e ) (e + e )  
2
3
4
to keep e 0V  
o
Figure 23. High input Z, DC differential amplifier Figure 24. High input Z adjustable gain DC  
instrumentation amplifier  
R1  
100k  
W
R4  
100k  
R3  
100k  
R4  
100k  
W
R2  
100k  
W
1/2  
LM158  
W
W
e1  
R1  
100k  
eO  
1/2  
LM158  
W
Gain adjust  
R3  
100k  
R2  
W
2k  
R5  
100k  
W
W
1/2  
LM158  
1/2  
LM158  
R6  
100k  
R7  
100k  
W
V
o
+V1  
+V2  
W
1/2  
LM158  
e2  
if R1 = R5 and  
if R1 = R5 and R3 = R4 = R6 = R7  
2R1  
R3 = R4 = R6 = R7  
e
= [1 +  
] ((e + e )  
2 1  
2R1  
] ((e + e )  
2 1  
-----------  
e
= [1 +  
o
-----------  
R2  
o
R2  
As shown e = 101 (e + e )  
o
2
1
As shown e = 101 (e + e )  
o
2
1
10/18  
LM158W-LM258W-LM358W  
Package information  
Figure 25. Using symmetrical amplifiers to  
reduce input current  
Figure 26. Low drift peak detector  
I
1/2  
LM158  
B
eo  
I I  
I
B
1/2  
LM158  
e I  
eo  
I
I
I
B
B
1/2  
LM158  
2N 929  
Zo  
C
2I  
e I  
B
1mF  
m
0.001 F  
ZI  
2N 929  
I
0.001  
m
F
B
B
I
2I  
B
1/2  
B
W
3M  
LM158  
R
1/2  
LM158  
3R  
3M  
1M  
W
Input current compensation  
W
I
B
Input current  
compensation  
W
1.5M  
I
B
Figure 27. Active band-pass filter  
R1  
100k  
W
C1  
330pF  
1/2  
R2  
100k  
R5  
470k  
LM158  
W
W
+V1  
R4  
10M  
W
1/2  
LM158  
C2  
R6  
470k  
330 F  
p
R3  
100k  
W
W
Vo  
1/2  
LM158  
R7  
100k  
W
VCC  
C3  
R8  
100k  
m
10  
F
W
5
Package information  
In order to meet environmental requirements, STMicroelectronics offers these devices in  
®
ECOPACK packages. These packages have a lead-free second level interconnect. The  
category of second level interconnect is marked on the package and on the inner box label,  
in compliance with JEDEC Standard JESD97. The maximum ratings related to soldering  
conditions are also marked on the inner box label. ECOPACK is an STMicroelectronics  
trademark. ECOPACK specifications are available at: www.st.com.  
11/18  
Package information  
LM158W-LM258W-LM358W  
5.1  
DIP8 package information  
Figure 28. DIP8 package mechanical drawing  
Table 4.  
Ref.  
DIP8 package mechanical data  
Millimeters  
Dimensions  
Inches  
Min.  
Typ.  
Max.  
Min.  
Typ.  
Max.  
A
a1  
B
3.3  
0.130  
0.7  
0.028  
0.055  
0.036  
1.39  
0.91  
1.65  
1.04  
0.065  
0.041  
B1  
b
0.5  
0.020  
b1  
D
E
0.38  
0.5  
9.8  
0.015  
0.020  
0.386  
8.8  
0.346  
0.100  
0.300  
0.300  
e
2.54  
7.62  
7.62  
e3  
e4  
F
7.1  
4.8  
0.280  
0.189  
I
L
3.3  
0.130  
Z
0.44  
1.6  
0.017  
0.063  
12/18  
LM158W-LM258W-LM358W  
Package information  
5.2  
SO-8 package information  
Figure 29. Package mechanical drawing  
Table 5.  
Ref.  
Package mechanical data  
Millimeters  
Dimensions  
Inches  
Min.  
Typ.  
Max.  
Min.  
Typ.  
Max.  
A
A1  
A2  
b
1.75  
0.25  
0.069  
0.010  
0.10  
1.25  
0.28  
0.17  
4.80  
5.80  
3.80  
0.004  
0.049  
0.011  
0.007  
0.189  
0.228  
0.150  
0.48  
0.23  
5.00  
6.20  
4.00  
0.019  
0.010  
0.197  
0.244  
0.157  
c
D
4.90  
6.00  
3.90  
1.27  
0.193  
0.236  
0.154  
0.050  
H
E1  
e
h
0.25  
0.40  
1°  
0.50  
1.27  
8°  
0.010  
0.016  
1°  
0.020  
0.050  
8°  
L
k
ccc  
0.10  
0.004  
13/18  
Package information  
LM158W-LM258W-LM358W  
5.3  
MiniSO-8 package information  
Figure 30. MiniSO-8 package mechanical drawing  
Table 6.  
Ref.  
MiniSO-8 package mechanical data  
Dimensions  
Millimeters  
Typ.  
Inches  
Min.  
Max.  
Min.  
Typ.  
Max.  
A
A1  
A2  
b
1.1  
0.043  
0.006  
0.037  
0.016  
0.009  
0.126  
0.203  
0.122  
0
0.15  
0.95  
0.40  
0.23  
3.20  
5.15  
3.10  
0
0.75  
0.22  
0.08  
2.80  
4.65  
2.80  
0.85  
0.030  
0.009  
0.003  
0.11  
0.033  
c
D
3.00  
4.90  
3.00  
0.65  
0.60  
0.95  
0.25  
0.118  
0.193  
0.118  
0.026  
0.024  
0.037  
0.010  
E
0.183  
0.11  
E1  
e
L
0.40  
0°  
0.80  
0.016  
0°  
0.031  
L1  
L2  
k
8°  
8°  
ccc  
0.10  
0.004  
14/18  
LM158W-LM258W-LM358W  
Package information  
5.4  
TSSOP8 package information  
Figure 31. TSSOP8 package mechanical drawing  
Dimensions  
Ref.  
Millimeters  
Typ.  
Inches  
Min.  
Max.  
Min.  
Typ.  
Max.  
A
A1  
A2  
b
1.2  
0.047  
0.006  
0.041  
0.012  
0.008  
0.122  
0.260  
0.177  
0.05  
0.80  
0.19  
0.09  
2.90  
6.20  
4.30  
0.15  
1.05  
0.30  
0.20  
3.10  
6.60  
4.50  
0.002  
0.031  
0.007  
0.004  
0.114  
0.244  
0.169  
1.00  
0.039  
c
D
3.00  
6.40  
4.40  
0.65  
0.118  
0.252  
0.173  
0.0256  
E
E1  
e
k
0°  
8°  
0°  
8°  
L
0.45  
0.60  
1
0.75  
0.018  
0.024  
0.039  
0.004  
0.030  
L1  
aaa  
0.1  
15/18  
Ordering information  
LM158W-LM258W-LM358W  
6
Ordering information  
Table 7.  
Order codes  
Temperature  
Order code  
Package  
Packaging  
Marking  
range  
LM158WN  
DIP-8  
SO-8  
DIP-8  
SO-8  
DIP-8  
SO-8  
Tube  
LM158WN  
158W  
-55°C, +125°C  
LM158WD  
LM158WDT  
Tube or  
tape & reel  
LM258WAN  
Tube  
LM258WA  
258WA  
LM258WAD  
LM258WADT  
Tube or  
tape & reel  
-40°C, +105°C  
LM258WN  
Tube  
LM258WN  
258W  
LM258WD  
LM258WDT  
Tube or  
tape & reel  
LM258WYPT (1)  
LM258AWYPT(1)  
258WY  
K410  
TSSOP8  
Tape & reel  
(Automotive grade)  
LM258WYD(2)  
40°C, +105°C  
0°C, +70°C  
0°C, +70°C  
258WY  
LM258WYDT (2)  
SO-8  
Tube or  
tape & reel  
LM258AWYD(2)  
LM258AWYDT(2)  
(Automotive grade)  
258AWY  
LM358WN  
358W  
LM358WN  
DIP-8  
SO-8  
Tube  
LM358WD  
LM358WDT  
Tube or  
tape & reel  
LM358AWD  
LM358AWDT  
358AW  
358WY  
358AWY  
LM358WYD(2)  
LM358WYDT(2)  
SO-8  
Tube or  
tape & reel  
LM358AWYD(2)  
LM358AWYDT(2)  
(Automotive grade)  
LM358WYPT(1)  
LM358AWYPT(1)  
358WY  
K411  
TSSOP8  
Tape & reel  
(Automotive grade)  
1. Qualification and characterization according to AEC Q100 and Q003 or equivalent, advanced screening  
according to AEC Q001 & Q 002 or equivalent are on-going.  
2. Qualified and characterized according to AEC Q100 and Q003 or equivalent, advanced screening  
according to AEC Q001 & Q 002 or equivalent.  
16/18  
LM158W-LM258W-LM358W  
Revision history  
7
Revision history  
Table 8.  
Date  
Document revision history  
Revision  
Changes  
01-Nov-2002  
01-Jul-2005  
1
2
First release.  
ESD protection inserted in Table 1: Absolute maximum ratings on  
page 3.  
ESD tolerance for model HBM improved to 2kV (Table 1: Absolute  
maximum ratings on page 3).  
06-Oct-2006  
3
Rthja and Rthjc typical values added in Table 1: Absolute maximum  
ratings on page 3.  
Added Figure 18: Phase margin vs. capacitive load on page 9.  
Order codes added (automotive grade level) to Section 6: Ordering  
information.  
02-Jan-2007  
15-Mar-2007  
25-Apr-2007  
4
5
6
Previously called revision 4.  
Footnote for automotive grade order codes added to Section 6:  
Ordering information.  
Added missing Revision 4 of January 2007 in revision history.  
Corrected revision number of March 2007 to Revision 5.  
Reformatted electrical characteristics table.  
Reformatted package information.  
11-Feb-2008  
7
Corrected MiniSO-8 package information.  
Corrected operating temperature range for automotive grade parts.  
17/18  
LM158W-LM258W-LM358W  
Please Read Carefully:  
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right to make changes, corrections, modifications or improvements, to this document, and the products and services described herein at any  
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All ST products are sold pursuant to ST’s terms and conditions of sale.  
Purchasers are solely responsible for the choice, selection and use of the ST products and services described herein, and ST assumes no  
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18/18  

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