This tool converts from **Voltage Gain** to **dB** or deciBel.

Enter the **Voltage Gain** (a positive real number) to get the equivalent **dB** value.

🔄 dB to Voltage Gain

**Formula**

**P _{dB} = 20*Log_{10}(V_{Gain})**

**V _{Gain}** =

**10**

^{(PdB/20)}**Notes**

- These formulas assume the input and output impedances are the same.
**V**is the ratio of two Root-mean-square voltage values (not the peak or average)_{Gain}**V**is always a positive number_{Gain}

**Example Calculations**

A voltage gain of 10 is equivalent to 20 dB. A voltage gain of 0.1 is equivalent to -20 dB.

**Background**

Gain is a measure of how many times one number is amplified by another. In this case, if the output voltage is 25 times the input power, then Vout:Vin = 25:1. Alternatively Vin:Vout is 1:25 and it can also be expressed as a fraction 1/25 or as a number 0.04.

Gain has no units as the input and the output are expressed in the same units. For instance, in this case it’s **Volt**.

The dB scale is a convenient way to represent both large and small numbers. For instance, the voltage ratio 10000000000:1 = 200 dB while 0.0000000001:1 = -200 dB.

The dB value does not have units. If a number A is 100 times greater than another number B, then on the log scale we can say that A is 20*Log_{10}(100) = 40 dB greater than B.

**Example calculation**

Let’s say an operational amplifier increases the input signal voltage by a factor of 100. The ratio of output to input is 100:1. Using the calculator, we can say that it is a 40 dB amplifier.

**Why Convert to dB?**

There are a few reasons for this. Here are a couple of main ones:

- the dB scale makes it easy to represent large and small ratios in fewer digits. For example a voltage ratio of 10000000 = 140 dB
- When making calculations in electronic systems such as calculating the gain in a transmitter chain,
*it’s easy to add and subtract gain and attenuation expressed in dB*. For example, consider a signal chain consisting of two amplifiers with gain levels 10 and 15 dB and a 3 dB insertion loss equates to a total gain of 22 dB. RF component vendors specify gain and attenuation in dB so it’s easy to get these numbers from a data sheet and even do the arithmetic mentally. Operating with linear values of Gain means you have to multiply and divide. It’s much more difficult to do this in your head.