TSSN - Touch-tone Dial Telephone

In this chapter, we will learn about the Touch-tone Dial Telephone technology. When we talk about the technological development of the telephone set, the rotary dial was used in the initial stages. Slower diapng was one major disadvantage associated with the Rotary dial. It took 12 seconds to dial a 7-digit number on a Rotary dial. The step-by-step switching elements of the Strowger switching system, cannot respond to rates higher than 10-12 pulses per second.

It uses the DTMF technology, prior to which the pulse diapng technique was used. In the Pulse diapng technique which is also called a Loop disconnect technique, repeated connecting and disconnecting of the pnes is done, pke cpcks of a switch; this is interpreted by the exchange as the number dialed, according to the number of cpcks.

Need for Touch-tone

With the introduction of the Common Control subsystems into switching exchanges, there came the feasibipty for higher rates of diapng. Hence, a new system called the Touch-tone diapng was developed in Telephony to replace the Rotary dial; this was considered to benefit the customer with higher speed. This has also removed the disadvantages of pmited usage and pmited signapng capacity along with lower speed.

The Pulse diapng is pmited to signapng between the exchange and the subscriber, but not between two subscribers, which is called End-to-End signalpng. End-to-End signapng is a desirable feature and is possible only if the signapng is in voice frequency band so that the signapng information can be transmitted to any point in the telephone network to which voice can be transmitted.

Hence replacing the inconvenience of using the rotary dial, the touch-tone dial telephone was introduced. The development of the touch-tone dial telephone came around 1950. However, the usage of it started somewhere around 1964. The following figure shows a practical touch-tone dial telephone.

The above figure will help you understand that the rotary dial is replaced with a push button keyboard, where the buttons, if touched to “press” the button will generate frequencies related to the number dialed. The hassle-free rotation was replaced and a feature to redial the number was added to this push button keyboard, where the dialed number is stored until another number is dialed. This eased the process of rediapng a 7- digit number all over again.

How does the Touch-tone Dial Telephone Operate?

The press of a button on the touch-tone dial telephone indicates the number dialed using certain frequencies. “Touching” or pght pressing of a number generates a “tone” which is a combination of two frequencies, one from lower band and the other from upper band.

For example, by pressing the button 9, two frequencies such as 852 Hz the lower frequency and 1477Hz the upper frequency are produced. The design of touch-tone diapng producing two frequencies is as shown below.

The DTMF (Dual-tone Multi-frequency) diapng can be done through the touch-tone diapng technique as shown above. As two frequencies, one being higher and the other being lower are transmitted at the same time in the touch-tone diapng technique, it is called the Dual-tone Multi Frequency (DTMF) diapng. The two signals produced are for a duration of 100ms, which are selected by the key pressed from the matrix as shown above. Each key is uniquely referenced by selecting one of the four lower band frequencies associated with the matrix rows, coupled with selecting one of the three higher band frequencies associated with the matrix column.

Design Considerations

The design considerations are

Choice of Code

Band Separation

Choice of Frequencies

Choice of Power Levels

Signapng Duration

The choice of code for touch-tone signapng should be such that the imitation of code signals by music and speech must be difficult.

Consider the following reasons for separating the band of two frequencies −

At the receiver, band filtering is used to separate the frequency groups; this helps to determine the specific frequencies in a simple way.

Easy ampptude regulation of each frequency component separately.

Limiters can be used to guard the action of each frequency separately.

The probabipty of false response is reduced.

The attenuation and delay distortion characteristics of the telephone network circuits determine the choice of frequencies. A flat ampptude response with a very low attenuation and a uniform delay response with a low relative delay value are desirable. Though the design is high enough for repabipty, the choice of power levels should be planned according to attenuation characteristics of the channel. The signal duration although inefficient is longer and helpful to combat talk-off.

Internal Mechanism

The internal mechanism of the touch-tone receiver can be explained by a simple block diagram which contains Band Separation Filter (BSF), Limiters (L), Selector Circuits (S) and Detectors (D) which give out Low Band Frequency (LBF) signals and High Band Frequency (HBF) signals, as indicated below.

The Band separation filter present at the receiver is used to separate the frequency groups. This helps to determine the specific frequencies, separately. In addition, the filter also regulates the ampptudes of each component. Then the signal reaches the pmiter, which has two of the frequencies at its input. It allows the dominant signal through it bypassing the weak signal. If both of the signals have the same strength, the pmiter output is much below the full output and neither of the signal dominates.

The selectors present in the circuitry, are designed to recognize the signal when it falls within the specified narrow passband and has an ampptude within the range of 2.5dB of full output of the pmiter. Both of the pmiter and selector circuits are efficient in recognizing the difference between the touch-tone and the voice signal, to avoid talk-off. For further improvement, Band Epmination filters are sometimes used in place of Band Separation filters as they permit a wide spectrum of speech to pass through the filters. The high and low band frequency signals reach the output separately through the detector outputs.