LT1213MJ8 データシートの表示(PDF) - Linear Technology
部品番号
コンポーネント説明
メーカー
LT1213MJ8 Datasheet PDF : 20 Pages
| |||
LT1213/LT1214
APPLICATI S I FOR ATIO
Supply Voltage
The LT1213/LT1214 op amps are fully functional and all
internal bias circuits are in regulation with 2.2V of supply.
The amplifiers will continue to function with as little as
1.5V, although the input common mode range and the
phase margin are about gone. The minimum operating
supply voltage is guaranteed by the PSRR tests which are
done with the input common mode equal to 500mV and a
minimum supply voltage of 2.5V. The LT1213/LT1214 are
guaranteed over the full – 55°C to 125°C range with a
minimum supply voltage of 2.5V.
The positive supply pin of the LT1213/LT1214 should be
bypassed with a small capacitor (about 0.01µF) within an
inch of the pin. When driving heavy loads and for good
settling time, an additional 4.7µF capacitor should be
used. When using split supplies, the same is true for the
negative supply pin.
Power Dissipation
The LT1213/LT1214 amplifiers combine high speed and
large output current drive into very small packages. Be-
cause these amplifiers work over a very wide supply range,
it is possible to exceed the maximum junction temperature
under certain conditions. To insure that the LT1213/
LT1214 are used properly, calculate the worst case power
dissipation, define the maximum ambient temperature,
select the appropriate package and then calculate the
maximum junction temperature.
The worst case amplifier power dissipation is the total of
the quiescent current times the total power supply voltage
plus the power in the IC due to the load. The quiescent
supply current of the LT1213/LT1214 has a positive tem-
perature coefficient. The maximum supply current of each
amplifier at 125°C is given by the following formula:
ISMAX = 4.2 + 0.048 × (VS – 5) in mA
VS is the total supply voltage.
The power in the IC due to the load is a function of the
output voltage, the supply voltage and load resistance. The
worst case occurs when the output voltage is at half
supply, if it can go that far, or its maximum value if it
cannot reach half supply.
For example, calculate the worst case power dissipation
while operating on ±15V supplies and driving a 500Ω load.
ISMAX = 4.2 + 0.048 × (30 – 5) = 5.4mA
PDMAX = 2 × VS × ISMAX + (VS – VOMAX) × VOMAX/RL
PDMAX = 2 × 15V × 5.4mA + (15V – 7.5V) × 7.5V/500
= 0.162 + 0.113 = 0.275 Watt per Amp
If this is the dual LT1213, the total power in the package is
twice that, or 0.550W. Now calculate how much the die
temperature will rise above the ambient. The total power
dissipation times the thermal resistance of the package
gives the amount of temperature rise. For this example, in
the SO-8 surface mount package, the thermal resistance is
150°C/W junction-to-ambient in still air.
Temperature Rise = PDMAX × θJA = 0.550W × 150°C/W
= 82.5°C
The maximum junction temperature allowed in the plastic
package is 150°C. Therefore the maximum ambient al-
lowed is the maximum junction temperature less the
temperature rise.
Maximum Ambient = 150°C – 82.5°C = 67.5°C
That means the SO-8 dual can be operated at or below
67.5°C on ±15V supplies with a 500Ω load.
As a guideline to help in the selection of the LT1213/
LT1214, the following table describes the maximum sup-
ply voltage that can be used with each part based on the
following assumptions:
1. The maximum ambient is 70°C or 125°C depending on
the part rating.
2. The load is 500Ω including the feedback resistors.
3. The output can be anywhere between the supplies.
PART
LT1213MJ8
LT1213CN8
LT1213CS8
LT1214CN
LT1214CS
MAX SUPPLIES
18.0V or ±14.1V
23.7V or ±18.0V
18.7V or ±14.7V
19.5V or ±15.4V
15.8V or ±12.2V
MAX POWER AT MAX TA
500mW
800mW
533mW
1143mW
800mW
13
Share Link: 