概要

説明

The ISL28633 is a 5V zero-drift rail-to-rail input/output (RRIO) Programmable Gain Instrumentation Amplifier (PGIA). This instrumentation amplifier features low offset, low noise, low gain error, and high CMRR. It is ideal for high precision applications over the wide industrial temperature range. This in-amp is designed with a unique 2-bit, 3-state logic interface that allows up to 9 selectable gain settings. The ISL2863x differential output amplifier includes a reference pin to set the common-mode output voltage to interface with differential input ADCs.

特長

  • Ultra-high precision front-end amplifier
  • Zero-drift instrumentation amplifier
  • Pin selectable 9 gain settings: G = 1 to 1,000
  • Rail-to-rail input/output
  • Differential output
  • RFI filtered inputs improve EMI rejection
  • Single supply: 2.5V to 5.5V
  • Dual supply: ±1.25V to ±2.75V
  • Low input offset: 5μV, Maximum
  • Low input offset drift: 50nV/°C, Maximum
  • High CMRR: 138dB, G = 100
  • Low gain error: <0.4%, All Gains, Maximum
  • Gain bandwidth: 2.3MHz
  • Input voltage noise (0.1Hz to 10Hz): 0.4μVP-P
  • Operating temperature range: -40 °C to +125 °C

製品比較

アプリケーション

アプリケーション

  • Pressure and strain gauge transducers
  • Weight scales
  • Flow sensors
  • Biometric: ECG/blood glucose
  • Temperature sensors
  • Test and measurement
  • Data acquisition systems
  • Low ohmic current sense

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モデル

ISL2853x/63xEV2Z Evaluation Kit Demo

The ISL2853x/63xEV2Z board allows simple evaluation of the ISL2853x and ISL2863x 5V zero drift programmable gain instrumentation amplifiers. Learn how easily you can set gain of amplifier anywhere from 1 to 1000.

Transcript

This is a video for the ISL2853x and ISL2863x programmable instrumentation amplifiers. These instrumentation amplifiers feature programmable gain capability internal to the IC, and is also using zero drift amplifier technology to build these instrumentation amplifiers. Let's take a look at what's inside this instrumentation amplifier, it is built off of the three amplifier topology as I mentioned earlier, and integrates the gain resistors to this instrumentation amplifier, and uses a digital control face interface to program the gain using two digital input pins.

Another addition to this instrumentation amplifier, as you could see on the bottom is an uncommitted extra op amp which provides flexibility on this chip, this op amp is uncommitted so you can use it for any other purposes that you would like. This amplifier is for the ISL2853x family. The other part in the family is the ISL2863x and looking in this chart right here, the only thing different is we've taken what was the uncommitted amplifier in the ISL2853x family and we've integrated it into the instrumentation amplifier path, and what this gives you is basically a fully differential amplifier or you have differential inputs and a differential output. So the family of ISL2863x amplifiers are ideal for driving high precision ADD converters with differential input front ends.

As I mentioned earlier, some of the benefits of this instrumentation amplifier is the zero drift technology used to build this in amp, looking at some of the key spec advantages for this amplifier some of the highlights are very low input offset voltage of 5µV, very high precision gain accuracy in the gain set resistors that are internal to the IC, and very low noise due to the zero drift technology. The other feature as I've mentioned earlier is the programmable gain of this amplifier, using two digital inputs we have a nine gain selection state depending on the part number of the amplifier for the ISL2853x and the ISL2863x, the gain ranges can be anywhere from one to 1000.

So in this video, I'm gonna be talking about the eval board which I show right here. Everything is populated for you to easily test out this IC, the gain setting switches you see are right here. There are three state switches, so high, low, and switch open, you got your inputs to the instrumentation amplifier on your left and the outputs to the instrumentation amplifier on the right, power supply connections at the top, and for the family of the ISL2853x this is the uncommitted amplifiers for the inputs and outputs.

If you look on the back of this amplifier, the gain set table for the device is on there so that you can easily configure the switches on the front to get the gain settings that you want based on which part you're using, so that you always have them on hand that you know how to quickly set the gain of the amplifier that you need. All right, what you see here is I have the eval board powered up with a bias of plus or minus 2.5V on the power supply, I'm putting in a signal of 50mV peak-to-peak into the amplifier, and what you see here on the oscilloscope is the input signal in yellow of 50mV peak-to-peak and at the output in blue, and then I can change the gain of these switches to program the gain on the amplifier that I want to put it in.

If I change XY scale at the highest gain of... I'm using the ISL28633 so the maximum gain is a 100 for the signal, so you could see I can dynamically program the gain with the two logic inputs. So this eval board is fully populated, it's very easy to use. Some of the key applications for the ISL2853x and ISL2863x family of instrumentation amplifiers, one commonly is for bridge-type applications where you have a bridge circuit and you're trying to amplify the signal on one leg of the bridge. Most commonly these bridge circuits would be for a strain gauge or a flow sensor, and in fact, in this what you see right here is a dedicated reference design for a 24-bit strain gauge front end amplifier. If you're interested in this reference design, you can actually find more information. There is an app note written for it, it is Application Note 1853.

Another typical application for an instrumentation amplifier is high side current sensing, so in this block diagram what you see here is one of our integrated FET buck regulators the ISL8024 acting as a DC to DC power supply and this example for an FPGA or an ASIC, so you have 3.3V coming into the buck regulator and then 1.2V coming out powering the low voltage FPGA. If you want to measure the power consumption of your FPGA you can implement this solution with a high side current sense using a very low value sense resistor, in this case it's 1mOhm.

Now, 1mOhm will not give you much of a voltage drop but at 4A of load current and given the fact that these instrumentation amplifiers are built with zero drift technology that enable very, very low voltage at the input because of the low noise performance of the amplifier, you can accurately measure the current sense signal using our ISL2853x or ISL2863x instrumentation amplifiers. And in the case of resistive current sensing especially at high currents, one of the concerns is the power loss of the current sense resistor.

Well, if you're gonna use a 1mOhm sense resistor even at 4A of full load current that this ISL8024 can deliver, that is only 16mW of power dissipation within the less sensing resistor. And if you noticed earlier, I gave the noise performance of the amplifier 0.1Hz to 10Hz for low frequency this thing has 250nV peak-to-peak of input noise. Well, you can sense down to a very low range of 10mA across 1mOhm and that gives you 10µV of a DC signal that is above the noise floor of the input stage of the amplifier because this amplifier is built with zero drift technology that has very, very low noise at the input.

So to conclude the video again, here's the picture of the eval board. Everything is integrated on this board for you to easily evaluate this IC. Again, just to reiterate it's a programmable gain amplifiers of these switches will set the gain of the amp from anywhere from one to 1,000, and on the back you can find the table, how to set the resistors to set the gain of the amplifier. And then, if you need more information there is a user's guide for this eval board. Thank you very much.