The bi-directional logic level converter is a very simple board that provides hassle free interface between systems operating on two different voltage levels.
Lets take an example to understand the problem and the solution. Say there are two systems where system 1 works on 5 volts and system 2 works on 3 volts. SO, all the high-output signals from system 1 will be at 5 volts and all the high-output systems from system 2 will be at 3 volts. Same goes for input signals. System 1 expects 5 volts and system 2 expects 3 volts.
While this might not seem to be a huge problem, in reality it is. It is dangerous particularly for system 2. The high voltage might deliver more current than the tolerance limit of system 2 and damage it. We need an interface between the two systems. An interface that will convert 5 volts signals from system 1 to 3 volts for system 2 and 3 volts signals from system 2 to 5 volts for system 1.
Although many people use a resistor based voltage divider network to get this job done, it is not a good solution. The resistor network is like this-
Can you see the problem here? The resistor values have to be recalculated every time there is change in voltage levels of any of the two or both systems. There is one other problem. While you can convert a higher voltage level to a lower one, you can’t do the reverse of it, i.e., You can convert say 5 volts to 3 volts but not 3 volts to 5 volts using this method.
The solution – A Bi-Directional Logic Level Converter
The Bi-Directional Logic Level converter is exactly what we need. In the image above, you can see the organization of the pins. One side is the high voltage (HV) side and the other side is the low voltage (LV) side. The signals from system 1 in our example connect on the HV side and the signals from system 2 connect on the LV side.
The working of the Bi-Directional Logic Level Converter
The working of the Bi-Directional Logic Level Converter is preety simple. We first have to define the two voltage levels. In our example, the HV is 5v and the LV is 3v. So, we have to connect the HV pin on the HV side to 5v and the LV pin on the LV side to 3v. Connect the ground of the 3v supply to GND on LV side and the ground of 5v supply to GND on HV side.
That done, its time to see how the signals operate. There are four remaining pins on either side of the converter, HV1 to HV4 and LV1 to LV4. A 5v signal on the HV1 pin will reflect as 3 volt on the LV1 pin and vice versa. Similarly for HV2, HV3 and HV4.
Lets continue with our example of the two systems. We will further break down our systems into individual signals each
- System 1 has two signals – A1(output) and B1(input)
- System 2 has two signals – A2(input) and B2(output)
A1 and B1 are 5 volt signals and A2 and B2 are 3 volt signals. Furthermore, A1 connects to A2 and B2 connects to B1.
We connect A1 to HV1 pin of the level converter and A2 to the LV1 pin. Similarly B1 pin to HV2 pin of the level converter and B2 pin to the LV2 pin.
Since A1 is output and A2 is input, any 5v signal on A1 will reflect as 3v on A2. Similarly, a 3v signal on B2 will be read as 5v signal on B1.
Thus, we have successfully interfaced two systems working on two different voltage levels.
Interfacing a USB to TTL converter with ESP8266
This is exactly how the ESP8266 is interfaced with a computer through a USB to TTL converter. The USB to TTL converter operates at 5v and the ESP8266 operates at 3.3v. In our example, the USB to TTL converter is system1 and the ESP8266 is system2. The only difference is that the ESP8266 operates at 3.3v instead of 3v.
In the above circuit, we have to connect RXD from the USB to TTL converter to Tx of ESP8266 and TXD from USB to TTL converter to Rx of ESP8266.