LCD Voltage Inputs for LCD Displays Explained

Dec 29, 2021 | Articles

Outline:

  1. LCD Voltage VCC, VDD, VSS, VEE, V0: The Basics Of LCD Power Inputs
  2. LCD Displays: What Do The C, D, S, And E Stand For?
  3. Why Vdd And Not Simply Vd?
  4. What Is V0 On An LCD?
  5. What Happens If The LCD Driving Voltage Is Too Low?
  6. What Happens If The LCD Driving Voltage Is Too High?
  7. Power Connections For A Custom LCD Display
  8. LCD Backlight Power Connections
  9. LCD Voltage Inputs And Charge Pumps

 This article is about LCD voltage inputs.

VCC, VDD, VSS, VEE, V0 Explained

Monochrome characters, graphic and static displays require different input voltages. All the different LCD voltage symbols can be confusing, but believe it or not, there is a system to the madness.

1. LCD Voltage: The Basics of LCD Power Inputs

The voltages VCC, VDD, VSS, and VEE are used in describing voltages at various common power supply terminals. The differences between these voltages stem from their origins in the transistor circuits they were originally used for.

This LCD voltage terminology originated from the terminals of each type of transistor and their common connections in logic circuits. In other words, VCC is often applied to BJT (Bipolar Junction Transistor) collectors, VEE to BJT emitters, VDD to FET (Field-Effect Transistor) drains, and VSS to FET sources. Most CMOS (Complementary metal-oxide-semiconductor) IC datasheets now use VCC and GND to designate the positive and negative supply pins.

In general VCC and VDD are used for positive voltage, and VSS and VEE are for ground.

2. LCD Displays: What Do the C, D, S, And E Stand For?

In the Pleistocene era (the 1960s or earlier), logic was implemented with bipolar transistors. NPN (Negative-Positive-Negative) was used because they were faster. It made sense to call positive supply voltage VCC where the “C” stands for the collector. The negative supply was called VEE where “E” stands for the emitter.

When FET transistor logic came around a similar naming convention was used, but now positive supply was VDD where “D” stands for a drain. The negative supply was called VSS where “S” stands for source. Now that CMOS is the most common logic this makes no sense. The “C” in CMOS is for “complementary” but the naming convention still persists. In practice today VCC/VDD means positive power supply voltage and VEE/VSS is for negative supply or ground.

3. Why VDD And Not Simply VD?

The convention of VAB means the voltage potential between VA and VB. The convention of using 3 letters was used to show power supply and ground reference voltages as well. In some cases, a processor may have both an analog and digital power supply. In this case, VCCA/VCCD and VSSA/VSSD are used. Another reason for the 3 letters is in an NPN circuit with a load resistor between the collector and VCC. VC would be the collector voltage. In this case, VCC is the positive power supply voltage and would be higher than VC.

Examples Of LCDS That Use This Nomenclature:

Below is the datasheet for a character LCD Display:

Pin one is called out as VSS which is also GND. Pin two is VDD or the positive power. Pin three (3) is Vo and is the difference in voltage between VDD and VSS. This LCD voltage is adjusted to provide the sharpest contrast. The adjustment can be accomplished through a fixed resistor or a variable potentiometer. Many products have firmware that monitors the temperature and automatically adjusts the contrast voltage.

4. What is V0 on an LCD?

In a Liquid Crystal Display (LCD), V0 is used to vary the screen brightness or contrast. Contrast, simply put is the ratio of the light areas to the dark areas in an LCD. This is usually done in a production setting with values that are optimized for most users. Temperature can have an undesirable effect on the display brightness and for this reason, a varying resister or potentiometer is used to accommodate the desires of the user.

Below is a datasheet of a 16×2 Character LCD module that shows various recommended driving voltages. The LCD voltage can range from MIN (minimum) to TYP (Typical) to Max (maximum).

5. What Happens if the LCD Driving Voltage is Too Low?

If the supplied LCD voltage drops too low, the display is ‘under-driven’ and will produce segments that are ‘grey’. The lower the LCD voltage falls below the acceptable threshold, the lower the contrast will be.

6. What Happens if the LCD Driving Voltage is Too High?

If the LCD is over-driven. This is where segments that should not be ‘on’ are gray. They are not as dark as the segments that should be on, but they can be seen and may cause confusion for the end-user.

7. Power Connections For a Custom LCD Display

There are times when a customer needs to replace a display that has been discontinued or EOL (End-Of-Life) by their previous LCD supplier. The previous LCD pin-outs may be different than our standard, off-the-shelf display. This is not a large problem to overcome.

We will redesign the PCB to match the customer’s old pinout. This will save the customer time and cost so that they will not need to redesign their PCB.

8. LED Backlight Power Connections

LED backlights are DC (Direct Current) driven and can be supplied from any one of three locations. The most popular is from pins 15 and 16. The second most popular option is to draw power from the ‘A’ and ‘K’ connections on the right side of the PCB.

The third option is to pull power from pins one and two. This is the same location from which the LCD is pulling its power.  We do not recommend this option and can modify the PCB for the customer to connect the backlight from a different location.

9. LCD voltage Inputs And Charge Pumps

Many LCD Modules will require more than one internal voltage/current. This may make it necessary for the customer to supply the needed inputs. They may need to supply 3V, 5V, 9V, -12V, etc.

The solution for this is to integrate a charge pump (or booster circuit) into the LCD circuitry. This solution works in most applications, but if the product will be operating in an intrinsic environment, care must be taken with the layout of the circuit board.

Intrinsically safe LCDs are Liquid Crystal Displays that are designed to operate in conditions where an arc or spark can cause an explosion. In these cases, charge pumps cannot be employed. In fact, the total capacitive value of the display needs to be kept to a minimum.

We do not build a display that is labeled ‘Intrinsically safe’ but we do design the LCD to meet the requirements of the engineer. In meeting the design engineer’s requirements, the display may need to contain two or three independent inputs. We can redesign the PCB and layout the traces to allow for these additional inputs.

Has your LCD display been discontinued or obsolete? Do you require a new supplier?

CreateXplay is able to reverse engineer and develop an equivalent LCD Display.

Call today or contact us.

Contact CreateXplay Now!

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