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ISL70617SEH Datasheet, PDF (20/28 Pages) Intersil Corporation – High voltage process control
ISL70617SEH
feedback common-mode input voltage, loop instability will result.
Therefore, the voltages at the ±VOUT pins should always be 3V
away from either rail, as shown in Equation 12.
VEE+ 3V < VOUT < VCC - 3V;
(EQ. 12)
where VOUT = |+VOUT| or |-VOUT|
Rail-to-Rail Differential ADC Driver
The differential output stage of the ISL70617SEH is designed to
drive the differential input stage of an ADC. In this configuration,
the VCO, VEO power supply pins connect directly to the ADC power
supply pins. This output swing arrangement is ideal for driving
the rail-to-rail ADC drive without the possibility of overdriving the
ADC input.
The output stage is capable of rail-to-rail operation when VCO, VEO
are powered from a single supply or from split supplies. It has a
single supply voltage range (VCO) from 3V to 15V (with VEO at
GND), and a ±1.5V to ±15V split supply voltage range. Under all
power supply conditions, VCC must be greater than VCO by 3V, and
VEE must be less than VEO by 3V to maintain the rail-to-rail output
drive capability.
The VCMO pin is an input to a very low bias current terminal and
sets the output common-mode reference voltage when driving a
differential input ADC, such that the output would have a ± input
signal span centered around an external DC reference voltage
applied to the VCMO pin.
Power Supply Voltages by Application
The ISL70617SEH can be adapted to a wide variety of
instrumentation amplifier applications where the signal source is
powered from supply voltages that are different from the supply
voltages powering downstream circuits. The following examples
are included as a guide to the proper connection and voltages
applied to the supply pins VCC, VEE, VCO, and VEO.
There are a common set of requirements across all power
applications:
1. A common ground connection from the input supplies, (VCC,
VEE) to the output supplies (VCO, VEO) is required for all
powering options.
2. The signal input pins (IN+, IN-) cannot float and must have a
DC return path to ground.
3. The input and output supplies cannot both be operated in
single supply mode due to the 3V feedback amplifier
common-mode headroom requirement in Equation 11.
The following are typical power examples:
EXAMPLE 1: BIPOLAR INPUT TO SINGLE SUPPLY
OUTPUT
The ISL70617SEH is configured as a 5V ADC driver in a high-gain
sensor bridge amplifier powered from a ±10V excitation source.
In this application, the ISL70617SEH must extract the low-level
bipolar sensor signal and shift the level to the 0V to +5V
differential rail-to-rail signal needed by the ADC. The following
powering option is recommended:
• VCC = +10V, VEE = -10V
• VCO = +5V, VEO = GND
• VCMO = +2.5V
• VCC, VEE power supply common connects to GND
EXAMPLE 2: HIGH VOLTAGE BIPOLAR I/O BUFFER
The ISL70617SEH is configured as a high impedance buffer
instrumentation amplifier in a ±15V industrial sensor
application. In this application, the ISL70617SEH must extract
and amplify the high impedance sensor signal and send it
downstream to a differential ADC operating from ±15V supplies.
The following powering options are recommended:
1. Input and output supplies are strapped to the same supplies
and rail-to-rail input to the ADC is not required.
- VCC = VCO = +15V
- VEE = VEO = -15V
- VCMO = GND
- VCC, VEE power supply common connects to GND
and VOUT = ±12V
2. ±15V rail-to-rail output is required, then:
- VCC = +18V, VEE = -18V
- VCO = +15V, VEO = -15V
- VCMO = GND
- VCC, VEE power supply common connects to GND
The VCO and VEO power supply pins connect to the ADC ±15V
power supply pins. Rail-to-rail output swing requires that
VCC = VCO +3V and VEE = VEO -3V, or ±18V.
EXAMPLE 3: GAINS LESS THAN 1
The ISL70617SEH is configured to a gain of 0.2V/V driving a
rail-to-rail 3V ADC. In this application, the maximum input
dynamic range is ±15V.
• VCC = +18V, VEE = -18V
• VCO = +3V, VEO = GND
• VCMO = +1.5V
• VCC, VEE power supply common connects to GND
In this attenuator configuration, the input signal range is ±15V,
which requires an additional ±3V of input overhead from the
input supplies. Thus, VCC and VEE = ±18V.
AC Performance Considerations
The ISL70617SEH closed loop frequency response is formed by
the feedback GM amplifier and gain resistor RFB and has the
characteristics of a current feedback amplifier. Therefore, the
-3dB gain does not significantly decrease at high gains as is the
case with the constant gain-bandwidth response of the classic
voltage feedback amplifier.
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FN8697.4
December 16, 2016