Lower DC voltage on single supply op-amp

In summary: It sounds like the TIA is not outputting a voltage that matches what you are inputting into the op-amp. The TIA may be outputting an AC voltage that is too low. Please check to see if the TIA is outputting a voltage that matches what you are inputting into the op-amp. If not, please provide the specs of the TIA so that I can purchase one and test it.
  • #1
dave6877
6
0
Howdy, I'm using the opa2350 op amp to amplify a <1mV signal by 2000. The problem is I want to have a greater gain (either second stage or larger feedback resistor) however the DC level is reaching too high so that it reaches over 2 V, and I need it under 2 V in order for a digital read into an Arduino. Does anyone have suggestions on how I can reduce the DC level? I would DC couple with a capacitor, however that would cut off half of my signal since it is a single supply op-amp, and I would rather not do that. Any help would be greatly appreciated.
 
Engineering news on Phys.org
  • #2
It sounds like your gain is higher than 2000 then? Maybe try just using a potentiometer to fine tune the gain for a set input (like input 1 mV and adjust til output is 2 V)?
 
  • #3
You need to explain a little more on the requirement. What is your input signal range from lowest to the highest DC voltage? What is the output range you want.

You need these before anyone can help you mapping the input to the output.
 
  • #4
Well here's the basic idea. Take in an optical AC signal into a photodiode, use a TIA to get a corresponding voltage. Projected output range of the TIA is from 0-200uV at 1kHz.

I want to amplify this AC signal to have (at minimum) a 2 Volt swing between 1.5 V and 2.5 V. These high and lows aren't required, however I do need the min to be below 2 V and the max to be above 3V.

I want a gain greater than 2000, it will probably end up being around 10000, however I can't implement this gain yet because I am having an offset DC voltage that is amplified from 1mV to 2V.
Is there a way to lower the DC level without using the DC coupled strategy that would end up cutting my signal in half since i am using a single-railed op amp??
 
  • #5
dave6877 said:
Well here's the basic idea. Take in an optical AC signal into a photodiode, use a TIA to get a corresponding voltage. Projected output range of the TIA is from 0-200uV at 1kHz.

I want to amplify this AC signal to have (at minimum) a 2 Volt swing between 1.5 V and 2.5 V. These high and lows aren't required, however I do need the min to be below 2 V and the max to be above 3V.
Between 1.5V and 2.5V is only one volt swing, not 2V!
I want a gain greater than 2000, it will probably end up being around 10000, however I can't implement this gain yet because I am having an offset DC voltage that is amplified from 1mV to 2V.
Is there a way to lower the DC level without using the DC coupled strategy that would end up cutting my signal in half since i am using a single-railed op amp??

As I expect, you need an op-amp circuit that has DC offset to match the input to output.

So far, you gave the output of the TIA with lower limit at 0V, high limit at +200uV. sounds like you want to map it to +2V to +3V. Please verify this, if not, give me the low limit and high limit of the required voltage. This is very important as you need to design two things, one is the full scale mapping of 200uVpp signal to say a 2Vpp signal where you need a gain of 10EE5. Then you have to map the DC offset. So these information is very important.
 
  • #6
yungman said:
As I expect, you need an op-amp circuit that has DC offset to match the input to output.

So far, you gave the output of the TIA with lower limit at 0V, high limit at +200uV. sounds like you want to map it to +2V to +3V. Please verify this, if not, give me the low limit and high limit of the required voltage. This is very important as you need to design two things, one is the full scale mapping of 200uVpp signal to say a 2Vpp signal where you need a gain of 10EE5. Then you have to map the DC offset. So these information is very important.
The DC output level of the TIA is at 1mV. The AC output is from that 0uV to 200uV.

So output of TIA = 1mV(1mV+0uV)(lower limit) to 1.2mV(1mV+200uV)(higher limit).

I need the output of the amplifier lower limit to be below 2V and the higher limit above 3V.
 
  • #7
dave6877 said:
Well here's the basic idea. Take in an optical AC signal into a photodiode, use a TIA to get a corresponding voltage. Projected output range of the TIA is from 0-200uV at 1kHz.

Why is the output of your first current-to-voltage stage so low? What is the source of the optical signal?
 
  • #8
My source is a red light (like a traffic light) from 45 ft away. I have a 75k feedback resistor that I chose through testing. It appeared that I got the largest gain out of the TIA before attenuation when the resistor was ~75k Ohms
 
  • #9
dave6877 said:
The DC output level of the TIA is at 1mV. The AC output is from that 0uV to 200uV.

So output of TIA = 1mV(1mV+0uV)(lower limit) to 1.2mV(1mV+200uV)(higher limit).

I need the output of the amplifier lower limit to be below 2V and the higher limit above 3V.

You have to tell me exactly the output, not just below 2V and above 3V, I use 2V and 3V here:

1) For signal, you want to map (0 to 0.2mV) to (0 to 1V)[itex]\Rightarrow\;[/itex] Gain=5000

2) DC offset is from 1mV to 2V so offset gain is 2000.

You are going to need two op-amp to do this.

Question:

1) what power supply do you have?
2) how stable is the 1mV offset of the TIA as I am not familiar with TIA. If it drift a lot, you are going to have problem.
3) Can you use two power supply so you can have +ve and -ve?
4) If the signal is 1KHz, can you use an AC coupling cap to get rid of the 1mV DC offset so you can start at ground level of -100uV to +100uV. This will eliminate a lot of uncertainty on the stability of the DC offset from the TIA.
5) can you accept inverted signal?

This is not exactly an easy circuit, you have to create an offset null for the offset. First pass, you need two inverting amp to do it. It would be more complicated if you have only positive supply and try to create the offset. If you can use an AC coupling cap, it is going to be easier, but you still are going to need 2 op-amp as you need a gain of 5000 and you need an op-amp of at least BGW of 5MHz or above. I don't like to use wide band op-amp if I don't need it.
 
Last edited:
  • #10
I apologize for my vague answers. Ideally, I need an output of 0(lower limit) to 3.5 V (higher limit).
(The reason for this is I am inputing this into an arduino digital input which reads a low as below 2V and a high as above 3V)

1) I am using a 5 V power supply from a pin on my arduino.
2) The 1mV output doesn't drift at all. It remains constant at 1mV.
3) I cannot use 2 power supplys because I am wanting this to be a portable device (hold in my hand). This is why I chose a single-supply opamp.
4) I have thought of using an AC coupling capacitor, however I have two problems with that.
a) I am not sure what value I should use for an AC coupling capacitor.
b) If I used an AC couple with a single supply op-amp, wouldn't it cut my signal in half (clipping the bottom half of my signal)?? I have looked for information on this, however I haven't been able to find much.

5) I can not accept an inverted signal. This is because I am inputting into a micro-controller, and I cannot alter the code within the microcontroller, so i have to input the exact signal the light is sending.

As I mentioned before, I am using the OPA2350.
Some stats for this op amp are.

GBW = 28 MHz
input offset voltage = 150uV
input bias current = +0.5 pA
 
  • #11
Here is the circuit, I have not calculate the resistor R1 or R2.

151207[/ATTACH]"]
3486dmp.jpg


I drew two circuit, first is with two op-amp, the second is with single op-amp. You can try either one. I set this to signal gain to 5000 to give range of 1V. I create the offset by R1 and R2 using a potentiometer.

As you can see, if you try straight gain of 5000, the output would want to go from 5V to 6V. When I use the R1 or R2 and pull to some positive voltage, that will drive the output of the opamp down. You can calculate the resistors to do the job. It is not that critical as you are using a potentiometer to adjust to the range you want. R1 and R2 has to be a few KΩ to minimize the effect on the gain as R1 or R2 is going to be in parallel with the 40Ω or the 4Ω resistor and change the gain a little. You adjust the potentiometer to get the offset of the output to the window you want.

I have not double check my work, I thought I post what I think and let to pick up and run a little first.

Also, I am using the +5V supply for voltage reference, any drift will cause error. But adding a voltage reference will be more complicated.
 

Attachments

  • 3486dmp.jpg
    3486dmp.jpg
    17.2 KB · Views: 345
Last edited:
  • #12
Wow, thank you so much. I will test this sometime in the next two days.

A couple questions:
1) What's the difference between the two? Is there a reason one would chose the circuitry with 2 opamps or is it just a matter of preference?

2) The pot in the bottom diagram. What's the value of the pot? I see in the top diagram has a pot of value 20k. Is the pot on the diagram 20k as well?

Thanks so much again.
 
  • #13
A 20K will be good.

I drew two as one stage implies the gain is 5000, kind of make me nervous. But you can try it as your amp is 28MHz.

I just put in some value to get the gain, you can massage the value according to the availability of the resistor. BTW, I don't like the 4Ω for one thing as you need so much gain AND I really don't like to use a large feedback resistor for a high speed amp either.
 

1. What is a single supply op-amp?

A single supply op-amp is a type of operational amplifier that operates with a single power supply instead of dual power supplies. This makes it more convenient and cost-effective to use in circuits.

2. Why would the DC voltage on a single supply op-amp be lower?

The DC voltage on a single supply op-amp may be lower due to a decrease in the power supply voltage. This can happen if the power supply is not providing enough voltage or if there is a voltage drop in the circuit.

3. What are the potential consequences of a lower DC voltage on a single supply op-amp?

A lower DC voltage on a single supply op-amp can result in decreased performance and accuracy of the op-amp. It may also cause the op-amp to operate in a non-linear region, leading to distortion in the output signal.

4. How can I troubleshoot a lower DC voltage on a single supply op-amp?

You can troubleshoot a lower DC voltage on a single supply op-amp by checking the power supply voltage and making sure it is within the recommended range for the op-amp. You can also check for any voltage drops in the circuit and make sure all connections are secure.

5. Are there any precautions I should take when using a single supply op-amp?

Yes, there are a few precautions to keep in mind when using a single supply op-amp. Make sure to use a power supply with the correct voltage and current rating, and avoid overloading the op-amp with too many inputs. It is also important to properly decouple the power supply to avoid noise and stability issues.

Similar threads

  • Electrical Engineering
Replies
8
Views
1K
Replies
2
Views
313
Replies
6
Views
2K
  • Electrical Engineering
Replies
6
Views
3K
  • Electrical Engineering
Replies
3
Views
761
Replies
9
Views
1K
  • Electrical Engineering
Replies
7
Views
3K
  • Electrical Engineering
Replies
25
Views
2K
  • Electrical Engineering
Replies
9
Views
3K
  • Electrical Engineering
Replies
9
Views
3K
Back
Top