The Incomplete Guide to Touchscreens Technologies


With the latest rumors about the support of Windows Mobile 6.5 to capacitive screens I decided to look for some more information about the different types of touch screens.

I decided to summarize the things I found in another "incomplete guide". Hope you'll Enjoy it.


-Before you continue!

Check out our previous mobile technologies guides:

How does 'Direct Push' work-

The History of PDAs

The Incomplete Guide to D-Pads

Different Screen Resolution in Windows Mobile Devices


The Incomplete Guide to Mobile Form Factors

More guides in here.

OK, now that we covered that one... let's begin:

The Incomplete Guide to TouchScreens Technologies!


Resistive Touchscreens:

A resistive touchscreen panel is composed of several layers, the most important of which are two thin, metallic, electrically conductive layers separated by a narrow gap.

When an object, such as a finger, presses down on a point on the panel's outer surface the two metallic layers become connected at that point: the panel then behaves as a pair of voltage dividers with connected outputs. This causes a change in the electrical current which is registered as a touch event and sent to the controller for processing.


This technology is pressure sensitive so it can be used with fingers, stylus, gloved hand, Spoon or even your elbow is you know how to control it good enough...

It's a cheap technology, very accurate when using stylus, and resistant to dirt, humidity etc.

Unlike what people think, resistive touchscreens can support Multitouch.

Surface acoustic wave

SAW technology uses ultrasonic waves that pass over the touchscreen panel. When the panel is touched, a portion of the wave is absorbed. This change in the ultrasonic waves registers the position of the touch event and sends this information to the controller for processing. Surface wave touchscreen panels can be damaged by outside elements or be contaminated... spooky.


Good old iPhone style capacitive touchscreen panel is a sensor typically made of glass coated with a transparent conductor such as indium tin oxide (ITO).

This type of sensor is basically a capacitor in which the plates are the overlapping areas between the horizontal and vertical axes in a grid pattern. Since the human body also conducts electricity, a touch on the surface of the sensor will affect the electric field and create a measurable change in the capacitance of the device. Like the stylus used in the defunct CED video disc, these sensors work on proximity of the conductive medium (finger), and do not have to be directly touched to be triggered. It is a durable technology that is used in a wide range of applications including point-of-sale systems, industrial controls, and public information kiosks.


Capacitive screens have a higher clarity than Resistive screens, but they only respond to finger contact and will not work with a gloved hand or pen stylus (unless the stylus is conductive which is annoying once you lose it...) - so they usually cannot support signature capturing etc.

On the other hand, the fact that you don't need to press the screen is so nice, it makes every phone operation smooth and fun.

Multitouch is of course supported...


Cannot use capacitive screens...

(It's a joke.. sure he can... once he turns into a real kid).


PenTouch Capacitive

This one is an interesting combination of both durable Capacitive technology with a tethered pen stylus. The screen can be set to respond to finger input only, pen input only, or both. The pen stylus is a good choice for signature capture, on-screen annotations, or for applications requiring precise input.


Conventional optical-touch systems use an array of infrared (IR) light-emitting diodes (LEDs) on two adjacent bezel edges of a display, with photosensors placed on the two opposite bezel edges to analyze the system and determine a touch event. The LED and photosensor pairs create a grid of light beams across the display. An object (such as a finger or pen) that touches the screen interrupts the light beams, causing a measured decrease in light at the corresponding photosensors. The measured photosensor outputs can be used to locate a touch-point coordinate.


Infrared touchscreens did not become popular as the other technologies because of their higher price, and because there is an issue with performance in bright ambient light. Oh, and multitouch is not supported...

Expensive and without multitouch...

Strain gauge

In a strain gauge configuration, also called force panel technology, the screen is spring-mounted on the four corners and strain gauges are used to determine deflection when the screen is touched.

This technology has been around since the 1960s but new advances by Vissumo and F-Origin have made the solution commercially viable.It can also measure the Z-axis and the force of a person's touch. Typically used in exposed public systems such as ticket machines due to their resistance to vandalism.

Optical imaging

A relatively-modern development in touchscreen technology, two or more image sensors are placed around the edges (mostly the corners) of the screen. Infrared backlights are placed in the camera's field of view on the other sides of the screen. A touch shows up as a shadow and each pair of cameras can then be triangulated to locate the touch or even measure the size of the touching object.

This technology is growing in popularity, due to its scalability, versatility, and affordability, especially for larger units.


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There are more touchscreens technologies: Acoustic pulse recognition, Dispersive signal and more, you can find more details in here.

Also, there are combinations of technologies, for instance, the Storm's touchscreen is a capacitive screen but it also includes a clickable surface. You can read more about it in here.

Here's a nice comparison between different touchscreens: 


Haptic/tactile touchscreens:

Some touchscreens include haptic feedback to ease the user experience when working on a flat surface with no real buttons.

One of the researches showed that when using haptic feedback users managed to reduce input errors (20%), increase input speed (20%), and lower their cognitive load (40%).

Interesting don't you think? Maybe this is why I liked the Omnia so much...

BTW, in some mobile devices, haptic feedback is built in,in others, it can be done using software only (a software that controls the vibration of the phone). Here's an example of such applications.


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Parrotlover77 said…
THANK YOU for posting this.  There is far too much misinformation about touch screens out there.  One of the WM blogs I frequent just never shuts up about capacitive screen rumors based on very flimsy information such as "look at the big finger friendly buttons - could it be for a capacitive screen?!?!"


Honestly, I like having a stylus.  Not for everyday operations, but sometimes it's great to have that precision.  It's like writing with a pen versus finger painting!  Finger touch centric devices and software for common tasks is fantastic.  But sometimes you don't want to finger paint!  :)

I'm getting off topic.  Anyway, thanks for clearing the air!

I would say, for the record that HTC's latest two generations of resistive screens have a pretty light touch.  Yes, it's not quite the same as the iPhone's virtual touchless touch, but compared to previous generations of WM phones, it feels really nice. 

My dream device has a Palm Pre slide down keyboard, large Touch Pro 2 screen and size, an exposed bottom D-Pad (no slide-out required) with at least four assignable buttons surrounding the D-Pad (XPeria X2 style layout), and a multitouch resistive screen with a nice substantial stylus with a built-in pen. Sigh...  I can dream...
Anonymous said…
Given the small display-size of most smartphones (<4 inch diagonal), but their high resolution (better than 480x320), it is obvious that their information density (pix/cm^2) cannot be adressed by a thick finger-tip. Only the thin tip of a stylus (or of a ladie's long finger-nail) can make good use of that information density. A typical example: cut-and-paste of text, starting and ending at a precise character. This is impossible for a finger-tip, since it is unprecise and the finger occludes the view.

This means that capacitive touchscreens, which require an extended surface of the finger to be in contact with the screen to register a "touch", are not at all appropriate for pocket-sized devices like smartphones when one tries to do more than just viewing information, but tries to actually modify the text/picture/etc. that is shown on the screen.

So far, only resistive touchscreens allow to work with a stylus or a finger-nail. For many users, this is really a more useful feature than being able to zoom with gestures (multi-touch feature of capacitive touchscreens). Zooming can be achieved in many other ways (for ex. by having a zoom-button, etc.). But nothing can replace pointing accuracy. Note that track-balls and other similar poiting-devices are no substitute for the ability to directly point to the screen with high accuracy.
In any case, technology already exists that allows to combine the advantages of capacitive and resistive displays, see for ex. (to whom I am related in no way). Unfortunately, this is being ignored in the newly released smartphones.

Stefan Fischer, University of Heidleberg (Germany).

PS> I cannot wait for Steve Jobs to introduce iFood, the revolutionary way to eat with your fingers, instead of with fork&knive ;-)
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A touchscreen is a visual show that can recognize the nearness and area of a touch to its surface, either from a finger or a protest, for example, a stylus. Various diverse innovations are being used on touchscreens, with the innovation to a substantial degree deciding reasonableness for use specifically situations and on what kind of gadget.