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If we connect the output of an op-a
If we connect the output of an op-amp to its inverting input and apply a voltage signal to the noninverting input, we find that the output voltage of the op-amp closely follows that input voltage (I've neglected to draw in the power supply, +V/-V wires, and ground symbol for simplicity):
As Vin increases, Vout will increase in accordance with the differential gain. However, as Vout increases, that output voltage is fed back to the inverting input, thereby acting to decrease the voltage differential between inputs, which acts to bring the output down. What will happen for any given voltage input is that the op-amp will output a voltage very nearly equal to Vin, but just low enough so that there's enough voltage difference left between Vin and the (-) input to be amplified to generate the output voltage.
The circuit will quickly reach a point of stability (known as equilibrium in physics), where the output voltage is just the right amount to maintain the right amount of differential, which in turn produces the right amount of output voltage. Taking the op-amp's output voltage and coupling it to the inverting input is a technique known as negative feedback, and it is the key to having a self-stabilizing system (this is true not only of op-amps, but of any dynamic system in general). This stability gives the op-amp the capacity to work in its linear (active) mode, as opposed to merely being saturated fully "on" or "off" as it was when used as a comparator, with no feedback at all.
Because the op-amp's gain is so high, the voltage on the inverting input can be maintained almost equal to Vin. Let's say that our op-amp has a differential voltage gain of 200,000. If Vin equals 6 volts, the output voltage will be 5.999970000149999 volts. This creates just enough differential voltage (6 volts - 5.999970000149999 volts = 29.99985 µV) to cause 5.999970000149999 volts to be manifested at the output terminal, and the system holds there in balance. As you can see, 29.99985 µV is not a lot of differential, so for practical calculations, we can assume that the differential voltage between the two input wires is held by negative feedback exactly at 0 volts.
As Vin increases, Vout will increase in accordance with the differential gain. However, as Vout increases, that output voltage is fed back to the inverting input, thereby acting to decrease the voltage differential between inputs, which acts to bring the output down. What will happen for any given voltage input is that the op-amp will output a voltage very nearly equal to Vin, but just low enough so that there's enough voltage difference left between Vin and the (-) input to be amplified to generate the output voltage.
The circuit will quickly reach a point of stability (known as equilibrium in physics), where the output voltage is just the right amount to maintain the right amount of differential, which in turn produces the right amount of output voltage. Taking the op-amp's output voltage and coupling it to the inverting input is a technique known as negative feedback, and it is the key to having a self-stabilizing system (this is true not only of op-amps, but of any dynamic system in general). This stability gives the op-amp the capacity to work in its linear (active) mode, as opposed to merely being saturated fully "on" or "off" as it was when used as a comparator, with no feedback at all.
Because the op-amp's gain is so high, the voltage on the inverting input can be maintained almost equal to Vin. Let's say that our op-amp has a differential voltage gain of 200,000. If Vin equals 6 volts, the output voltage will be 5.999970000149999 volts. This creates just enough differential voltage (6 volts - 5.999970000149999 volts = 29.99985 µV) to cause 5.999970000149999 volts to be manifested at the output terminal, and the system holds there in balance. As you can see, 29.99985 µV is not a lot of differential, so for practical calculations, we can assume that the differential voltage between the two input wires is held by negative feedback exactly at 0 volts.
0/5000
If we connect the output of an op-amp to its inverting input and apply a voltage signal to the noninverting input, we find that the output voltage of the op-amp closely follows that input voltage (I've neglected to draw in the power supply, +V/-V wires, and ground symbol for simplicity):
As Vin increases, Vout will increase in accordance with the differential gain. However, as Vout increases, that output voltage is fed back to the inverting input, thereby acting to decrease the voltage differential between inputs, which acts to bring the output down. What will happen for any given voltage input is that the op-amp will output a voltage very nearly equal to Vin, but just low enough so that there's enough voltage difference left between Vin and the (-) input to be amplified to generate the output voltage.
The circuit will quickly reach a point of stability (known as equilibrium in physics), where the output voltage is just the right amount to maintain the right amount of differential, which in turn produces the right amount of output voltage. Taking the op-amp's output voltage and coupling it to the inverting input is a technique known as negative feedback, and it is the key to having a self-stabilizing system (this is true not only of op-amps, but of any dynamic system in general). This stability gives the op-amp the capacity to work in its linear (active) mode, as opposed to merely being saturated fully "on" or "off" as it was when used as a comparator, with no feedback at all.
Because the op-amp's gain is so high, the voltage on the inverting input can be maintained almost equal to Vin. Let's say that our op-amp has a differential voltage gain of 200,000. If Vin equals 6 volts, the output voltage will be 5.999970000149999 volts. This creates just enough differential voltage (6 volts - 5.999970000149999 volts = 29.99985 µV) to cause 5.999970000149999 volts to be manifested at the output terminal, and the system holds there in balance. As you can see, 29.99985 µV is not a lot of differential, so for practical calculations, we can assume that the differential voltage between the two input wires is held by negative feedback exactly at 0 volts.
As Vin increases, Vout will increase in accordance with the differential gain. However, as Vout increases, that output voltage is fed back to the inverting input, thereby acting to decrease the voltage differential between inputs, which acts to bring the output down. What will happen for any given voltage input is that the op-amp will output a voltage very nearly equal to Vin, but just low enough so that there's enough voltage difference left between Vin and the (-) input to be amplified to generate the output voltage.
The circuit will quickly reach a point of stability (known as equilibrium in physics), where the output voltage is just the right amount to maintain the right amount of differential, which in turn produces the right amount of output voltage. Taking the op-amp's output voltage and coupling it to the inverting input is a technique known as negative feedback, and it is the key to having a self-stabilizing system (this is true not only of op-amps, but of any dynamic system in general). This stability gives the op-amp the capacity to work in its linear (active) mode, as opposed to merely being saturated fully "on" or "off" as it was when used as a comparator, with no feedback at all.
Because the op-amp's gain is so high, the voltage on the inverting input can be maintained almost equal to Vin. Let's say that our op-amp has a differential voltage gain of 200,000. If Vin equals 6 volts, the output voltage will be 5.999970000149999 volts. This creates just enough differential voltage (6 volts - 5.999970000149999 volts = 29.99985 µV) to cause 5.999970000149999 volts to be manifested at the output terminal, and the system holds there in balance. As you can see, 29.99985 µV is not a lot of differential, so for practical calculations, we can assume that the differential voltage between the two input wires is held by negative feedback exactly at 0 volts.
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Nếu chúng tôi kết nối đầu ra của một op-amp để đảo ngược đầu vào của nó và áp dụng một tín hiệu điện áp đầu vào noninverting, chúng ta thấy rằng điện áp đầu ra của op-amp theo sát mà điện áp đầu vào (tôi đã bỏ rơi để vẽ trong điện cung cấp, + dây V / V, và đất tượng trưng cho sự đơn giản): Khi Vin tăng, Vout cũng tăng theo với mức tăng khác biệt. Tuy nhiên, như Vout tăng, mà điện áp đầu ra là ăn trở lại inverting đầu vào, do đó làm giảm sự khác biệt điện áp giữa đầu vào, có tác dụng mang lại sản lượng xuống. Điều gì sẽ xảy ra đối với bất kỳ điện áp đầu vào do là các op-amp sẽ ra một điện áp rất gần bằng với Vin, nhưng chỉ đủ thấp để có đủ điện áp lệch trái giữa Vin và (-) đầu vào được khuếch đại để tạo ra sản lượng điện áp. Các mạch sẽ nhanh chóng đạt đến một điểm của sự ổn định (được gọi là trạng thái cân bằng trong vật lý), nơi điện áp đầu ra là số tiền vừa phải để duy trì đủ lượng phân, do đó sản xuất đủ lượng điện áp đầu ra. Lấy điện áp đầu ra của op-amp và ghép nó vào nghịch đảo đầu vào là một kỹ thuật được gọi là phản hồi tiêu cực, và nó là chìa khóa để có một hệ thống tự ổn định (điều này không chỉ đúng trong op-amps, nhưng trong bất kỳ hệ thống năng động nói chung). Sự ổn định này mang lại cho các op-amp khả năng làm việc ở tuyến tính (đang hoạt động) Chế độ của nó, như trái ngược với chỉ được bão hòa hoàn toàn "trên" hoặc "tắt" như khi sử dụng như một so sánh, không có phản hồi nào cả. Bởi vì tăng op-amp được quá cao, điện áp trên inverting đầu vào có thể được duy trì gần như bằng Vin. Hãy nói rằng chúng tôi op-amp có một tăng điện áp khác biệt của 200.000. Nếu Vin bằng 6 volts, điện áp đầu ra sẽ được 5,999970000149999 volt. Điều này tạo ra chỉ đủ điện áp khác biệt (6 volts - 5,999970000149999 volt = 29,99985 μV) để gây 5,999970000149999 volt để được thể hiện ở thiết bị đầu cuối đầu ra, và hệ thống các tổ chức có được cân bằng. Như bạn có thể thấy, 29,99985 μV không phải là rất nhiều khác biệt, vì vậy đối với tính toán thực tế, chúng ta có thể giả định rằng các điện áp khác biệt giữa hai dây đầu vào được tổ chức bởi phản hồi tiêu cực chính xác ở 0 volt.
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