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MIC7122 Datasheet, PDF (6/8 Pages) Micrel Semiconductor – Rail-to-Rail Dual Op Amp Preliminary Information
MIC7122
Application Information
Input Common-Mode Voltage
The MIC7122 tolerates input overdrive by at least 300mV
beyond either rail without producing phase inversion.
If the absolute maximum input voltage is exceeded, the input
current should be limited to ±5mA maximum to prevent
reducing reliability. A 10kΩ series input resistor, used as a
current limiter, will protect the input structure from voltages as
large as 50V above the supply or below ground. See Figure
1.
RIN
VIN
10kΩ
VOUT
Figure 1. Input Current-Limit Protection
Output Voltage Swing
Sink and source output resistances of the MIC7122 are
equal. Maximum output voltage swing is determined by the
load and the approximate output resistance. The output
resistance is:
ROUT
=
VDROP
ILOAD
VDROP is the voltage dropped within the amplifier output
stage. VDROP and ILOAD can be determined from the VO
(output swing) portion of the appropriate Electrical Character-
istics table. ILOAD is equal to the typical output high voltage
minus V+/2 and divided by RLOAD. For example, using the
Electrical Characteristics DC (5V) table, the typical output
high voltage drops 13mV using a 2kΩ load (connected to V+/
2), which produces an ILOAD of:
5.0V
–
0.013V
2kΩ
–
2.5V
=
1.244mA
Because of output stage symmetry, the corresponding typical
output low voltage (13mV) also equals VDROP. Then:
ROUT
=
0.013V
0.001244A
=
10.5Ω
Power Dissipation
The MIC7122 output drive capability requires considering
power dissipation. If the load impedance is low, it is possible
to damage the device by exceeding the 125°C junction
temperature rating.
On-chip power consists of two components: supply power
and output stage power. Supply power (PS) is the product of
the supply voltage (VS = VV+ – VV–) and supply current (IS).
Output stage power (PO) is the product of the output stage
Micrel
voltage drop (VDROP) and the output (load) current (IOUT).
Total on-chip power dissipation is:
PD = PS + PO
PD = VS IS + VDROP IOUT
where:
PD = total on-chip power
PS = supply power dissipation
PO = output power dissipation
VS = VV+ – VV–
IS = power supply current
VDROP = VV+ – VOUT
(sourcing current)
VDROP = VOUT – VV–
(sinking current)
The above addresses only steady state (dc) conditions. For
non-dc conditions the user must estimate power dissipation
based on rms value of the signal.
The task is one of determining the allowable on-chip power
dissipation for operation at a given ambient temperature and
power supply voltage. From this determination, one may
calculate the maximum allowable power dissipation and,
after subtracting PS, determine the maximum allowable load
current, which in turn can be used to determine the miniumum
load impedance that may safely be driven. The calculation is
summarized below.
PD(max)
=
TJ(max) −
θJA
TA
θJA(MSOP-8) = 200°C/W
Driving Capacitive Loads
Driving a capacitive load introduces phase-lag into the output
signal, and this in turn reduces op-amp system phase margin.
The application that is least forgiving of reduced phase
margin is a unity gain amplifier. The MIC7122 can typically
drive a 200pF capacitive load connected directly to the output
when configured as a unity-gain amplifier and powered with
a 2.2V supply. At 15V operation the circuit typically drives
500pF.
Using Large-Value Feedback Resistors
A large-value feedback resistor (> 500kΩ) can reduce the
phase margin of a system. This occurs when the feedback
resistor acts in conjunction with input capacitance to create
phase lag in the feedback signal. Input capacitance is usually
a combination of input circuit components and other parasitic
capacitance, such as amplifier input capacitance and stray
printed circuit board capacitance.
Figure 2 illustrates a method of compensating phase lag
caused by using a large-value feedback resistor. Feedback
capacitor CFB introduces sufficient phase lead to overcome
the phase lag caused by feedback resistor RFB and input
MIC7122
6
March 1999