There are many types of touch panel technologies available in the market, the popular types are resistive touch panel (RTP), surface capacitive touch panel, projected capacitive touch panel (PCAP or CTP), surface acoustic wave (SAW) touch panel, Infrared (IR) touch panel. The reason each type of touchscreen responds so differently is the underlying technology. In this article, we are going to discuss the two most widely used types, and compare resistive vs capacitive touch screen
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Capacitive touch screen
Projected Capacitive Touch Panel (PCAP) was actually invented 10 years earlier than the first resistive touchscreen. But it was no popular until Apple first used it in iPhone in . After that, PCAP dominates the touch market, such as mobile phones, IT, automotive, home appliances, industrial, IoT, military, aviation, ATMs, kiosks, Android cell phones etc.
Projected capacitive touchscreen contains X and Y electrodes with insulation layer between them. The transparent electrodes are normally made into diamond pattern with ITO and with metal bridge.
Fig. 1. P-CAP X and Y electrode structure
Fig. 2. Metal Bridge in P-CAP
Human body is conductive because it contains water. Projected capacitive technology makes use of conductivity of human body. When a bare finger touches the sensor with the pattern of X and Y electrodes, a capacitance coupling happens between the human finger and the electrodes which makes change of the electrostatic capacitance between the X and Y electrodes. The touchscreen controller detects the electrostatic field change and the location.
Fig. 3. Projected Capacitive Touch Sensor
Capacitive Touchscreen Advantages
In There are many advantages for P-CAP:
Projected capacitive supports multiple touches (Multi-touch), so it supports a lot of gestures: Zoom in and out (pinch/spread), scroll, swipe, drag, slide, hold/press, rotate, tap etc.
Excellent image clarity because of high transmission.
Excellent sensitivity.
More resistance to the scratches because the surface can be made by tampered glass, such as gorilla glass or dragontrail glass which can have the surface hardness of 9H. Only diamond can make a scratch.
Resistance to contaminants and liquid. It is easier to get clean of dust, grease, moisture etc.
With the new development, projected capacitive touch panels can support gloved hand touch with different glove materials and touch with water or even with salt water.
Resistive Touchscreen: Introduction
Before , resistive technology was the most popular touch panel market. From its name, we know that the technology relies on resistance. A resistive touch screen is made of a glass substrate as the bottom layer and a film substrate (normally, clear poly-carbonate or PET) as the top layer, each coated with a transparent conductive layer (ITO: Indium Tin Oxide), separated by spacer dots to make a small air gap. The two conducting layers of material (ITO) face each other. When a user touches the part of the screen with finger or a stylus, the conductive ITO thin layers contacted. It changes the resistance. The RTP controller detects the change and calculate the touch position. The point of contact is detected by this change in voltage.
Fig. 4. Resistive Touchscreen Technology (RTP)
Resistive Touchscreens Advantages
With the fast development of projected capacitive, resistive touchscreen devices market is shrinking rapidly but it is still widely used in some industrial applications because of the following advantages.
Low cost and simple manufacturing process.
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Low power consumption and easy drive.
Easily be activated with any touch material as long as the pressure is applied (finger, stylus, glove, pen etc.) (not keys to cause scratches on surface).
Robust during harsh climate and rugged environment and no false touch.
Resistive vs capacitive touch Screens
The following table shows the comparison of resistive and capacitive touch screens. It is up to your application to select the types of technology to use.
Resistive Touch Sensor
Capacitive Touch Sensor
Cost
Low
Relatively high, can be low for especial design
Multi-touch
No
Yes
Touch Gestures
Difficult
Yes
Touch Durability
3H, easy scratch
Can be as high as 9H, hard to scratch
Power Consumption
Lower
Higher
Touch Sensitivity
Low
High (Adjustable)
Touch Resolution
High
Relatively low
Image Clarity
Poor
Good
Touch Material
Any type
Fingers. Can be designed to use other materials like glove, stylus, pencil etc.
Touch with water, oil
No design change
Need special design
Surface Decoration
Difficult
Easy
Different Shape
Difficult
Easy
Overlay
Can be done
No
3D surface
Difficult
Achievable
Size
Small to medium size
Small to very big size
Under Rugged Environment
Easy
Difficult
False Touch
No
Need careful calibration
functionality Sensitive to EMI/RFI
Low
High, shield has to be designed
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Touchscreens are everywhere. From the coffee maker in the breakroom to the smartwatch on your childs wrist to the in-flight entertainment system on your commuter flight, touchscreen technologies are a part of our everyday lives. As touchscreens continue to become intertwined in our culture, they help make everyday tasks that much simpler and improve the ease of use for all kinds of electronics.
For example, airport kiosks with fully integrated touchscreens have helped make checking luggage a painless process. After a few taps on an airplanes GPS screen, a captain can enter new latitude and longitude coordinates. With a few swipes on a smartphone, a family member can send a 200-character text message. Touchscreens are used in nearly all industries including medical devices , military and aerospace equipment , industrial equipment , and consumer products .
For those that remember the days of T9 predictive text (which thanks to touchscreens is no longer required), creating text messages with a 9-button keypad was less than efficient. Looking further into the past, touchscreens developed in the s were considered futuristic with only a handful of products available. Most were resistive style overlays that were paired with CRT monitors. These devices were bulky, wildly expensive, and offered limited functionality. The smartphone revolution of the late s helped catapult touchscreens into our daily lives while driving down costs. Electronics owners are now able to interface with their devices faster, with fewer steps or taps, and with increased efficiency. Considering the net benefit to the Users experience, many are willing to pay a premium for devices with touchscreens.
Surprisingly, custom touchscreen technologies can be quite affordable and a viable option for prototype manufacturing
ATMs are frequently designed with resistive touchscreen interfaces.
Resistive vs Capacitive Touchscreens
Touchscreens range in complexity and cost. The most common types of touch panels are resistive and capacitive touchscreens . While most touchscreens on the market today are the capacitive touch variety, this type requires specialty microcontrollers and firmware to integrate within the next higher assembly. Capacitive style touchscreens function by detecting a change in capacitance.
Capacitive touch displays are designed to respond to a human finger, a stylus, or another conductive instrument. One of the drawbacks to using capacitive touchscreens is that they seldom function with heavy gloves or electrically insulating mitts.
Resistive touchscreens can be operated with a simple calibration step and any instrument that can apply a point force to the screen. Resistive touch panels function no matter what type of gloves are worn by the user. They can successfully operate while covered in contaminants like dirt, salt deposits, and condensation. If the end-user is expected to be wearing heavy gloves, or the end application is especially dirty, resistive style touchscreens are a worthy solution and should be considered.
Resistive touch panels are available in a handful of different architectures, each with their own set of pros and cons. Of the three types of resistive touch panels (4-wire, 5-wire, and 8-wire), the 5-wire design is one of the most common and represents a high-performance and low-cost design solution. Epec recommends 5-wire designs when no specific design architecture is specified.
Resistive touch panels are comprised of glass and electrically conductive films separated by a small air gap. The touchscreen layers contain a transparent conductive coating, usually Indium Tin Oxide (ITO) that is deposited across the surface of the film. The panel is sectioned into quadrants, and each is electrically connected to a small flexible tail extending off one of the edges. This tail can be plugged directly into the mating control board for operation.
Resistive touchscreens function by applying a slight point force to the screen. When a finger or stylus touches the panel, a small amount of current is drawn to the contact point creating a voltage drop. The current flow from each quadrant is proportional to the distance to the location depressed on the screen. The location on the screen is then interpolated using a known algorithm that equates the measured resistance to a known calibration table.
Resistive Touchscreen Customization
With limited off-the-shelf choices for resistive touchscreens, designers should note custom production runs are a viable option when the required touchscreen solution cannot be found. When designed using readily available materials and processes, these devices can be extremely inexpensive and built within lead times comparable to circuit board assemblies.
Though many touchscreen overlays + LCD displays can be bought together as an off-the-shelf pair, the overlay can be designed separately from the LCD/LED/OLED display that they intend to be assembled with. Resistive touchscreens are matched to the size of the corresponding display. Custom-sized resistive touchscreens are common and straightforward designs as long as specs are available for the paired display. Custom touchscreens are manufactured from dimensional information on the LCD displays datasheet. The information required to make a custom resistive touchscreen includes: the outline dimensions, the screens viewing area, and the touch-sense activation area. Custom resistive overlays can be produced in sizes of less than 3 inches, and larger than 21 inches. Most projects require a small non-recurring tooling expense to launch production.
Touchscreens are considered low voltage devices that typically operate at less than 5VDC and only milliamps of current. Customization measures can include adding anti-UV coatings, EMI shielding, and discrete components like LEDs or surface-mounted devices to the frame. The flexible tails used to connect the overlay to the primary PCBA are usually 1mm pitch Zero Insertion Force (ZIF) tails. The exact pin count, pin pitch, and ZIF tail stiffener geometries can be customized to the mating ZIF connector. Customers can specify their preferred board-mounted connector and Epec will develop a ZIF tail to properly match. To validate the design, Epec supplies a detailed manufacturing drawing that defines the pinout, dimensional information, and all performance requirements.
Custom manufactured resistive touchscreens with ZIF tail.
Summary
Considering that many electronics distributors carry standard-sized touchscreens in stock, buying a few for early prototyping is good engineering practice and can be accomplished for less than $50. Once the design is matured to a point where system requirements can be expanded, a full-service manufacturing partner like Epec can design and fabricate custom touchscreens to the exact size and level of function that the project demands.
Many of the design challenges that exist when considering touch overlays can be quickly remedied with a custom solution. Whether its extending the length of a ZIF tail, adding shielding, or reducing the activation area, touchscreen manufacturers like Epec can help drive risk out of the process. Starting that process early is always recommended, especially in times of global supply chain struggles.
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