What is the future of television?
In future, there will be more merging of functions of your cellphone and TV. TV will be a screen for your cellphone, for example. Also expect more VR, AR and ultra-high definition TV
image for illustrative purpose
Look at your modern-day TV, and you see nothing less than a technological miracle. Scientists began experimenting with the concept of television more than a century ago. But decades would pass before the Radio Corporation of America brought it to the public at the 1939 World's Fair. More time passed before TV sets were in stores – and even then, it took awhile until most people had one. In 1950, fewer than 10 per cent of Americans owned a television. By 1959, that number had grown to 85 per cent. During the '50s, TVs were expensive, screens were small and the picture wasn't always crystal clear. What's more, early TV programmes were in black and white; colour wasn't in wide use until the mid-1960s. Viewers didn't have a lot of choice, either. Instead of hundreds of channels to choose from, most cities offered only three or four. And DVR didn't exist. Programmes appeared on a specific day at a particular time, and if you missed it – you missed it. As a professor of electrical and computer engineering, I am amazed by the remarkable advances of this technology in only a few decades.
Yet whether an early television with a 5-inch screen, or one of today's smart TVs that practically cover the wall, your set still has three primary functions: to receive audio and video data; to use that data to present the viewer with sound and a picture; and to provide the viewer with a way to set the channel and the volume. Radio waves, transmission towers and antennas Early TVs worked with the use of "analog signals" – essentially radio waves containing both the picture and sound of a television programme.
Simply put, here's how it worked: Using a giant transmission tower, the local television station repeatedly sent those radio waves through the air during the broadcast day. Antennas on the roofs of buildings and homes in the community intercepted those waves and, through a cable, transported the signal to the television sets inside. There, the TV unscrambled the signal and turned it into a picture with sound. What you saw and heard wasn't as sharp as today's TVs, but it was good. By 2009, TV stations replaced analog signals with digital TV signals, which is the standard used today. HDTV, or high-definition television, has an amazing picture quality compared to earlier TVs. Digital signals are still transmitted using radio waves, but the TV picture is encoded in binary – that is, a series of 0s and 1s. Bits, bytes and frames Modern digital TV uses different information streams. For example, one stream is for the picture; another stream is for the audio. Pictures are created by basic units called pixels. Your TV screen has tens of thousands of pixels, and each one has a "colour index" and an "intensity."
Basically, three colours – red, blue and green – form other colours in various combinations, and the picture is ultimately created from all the pixels together forming an image. Just like mixing paint to make any colour you wish, varying the amount and intensity of each of the colour pixels creates the desired image. Groups of bits are formed into larger units called bytes. They are the communication link between the content you are watching and your TV.
A modem packages and unpackages this information; at its heart, every TV or cellphone is based on a modem. The packaged information can be transmitted over the air or sent via fibre or cable, where they come into your TV via a cable box. Streaming TV, a service that has become very popular, takes data from a computer network. Then it's up to you, the viewer. Your modern digital smart TV has an interface that allows you to control all the functions. Basically, a smart TV is a computer, large monitor and receiver all in one package. In the future, there will be more merging of the functions of your cellphone and TV. The TV will be a screen for your cellphone, for example. Also expect more virtual reality (VR), augmented reality (AR) and ultra-high definition TV.
(The author is Professor of Electrical and Computer Engineering, UMass Lowell)