Time division multiplexing is used when the data to be transmitted isa...
Time-division multiplexing (TDM) is a method of transmitting and receiving independent signals over a common signal path by means of synchronized switches at each end of the transmission line so that each signal appears on the line only a fraction of time in an alternating pattern.
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Time division multiplexing is used when the data to be transmitted isa...
Time Division Multiplexing (TDM)
Introduction
Time Division Multiplexing (TDM) is a digital communication technique that allows multiple signals to be transmitted over a single communication channel by dividing the available time into multiple time slots. Each signal is allocated a specific time slot, and the signals are interleaved to form a composite signal for transmission.
Advantages of TDM
TDM offers several advantages, including:
- Efficient utilization of a communication channel by allowing multiple signals to share the same physical medium.
- Simplicity of implementation, as it requires only a time-sequencing mechanism at the transmitter and receiver.
- Flexibility in accommodating signals with varying bandwidth requirements.
Selection of TDM
To determine when to use TDM, we need to consider the characteristics of the data to be transmitted.
Slow Changing Data
Slowly changing data refers to signals that do not change rapidly over time. Examples include voice signals, temperature readings, and slow-speed sensors. These signals do not require a high sampling rate to accurately represent their characteristics. TDM is suitable for such signals because it allows the available time slots to be allocated to multiple slow-changing signals.
Small Bandwidth Data
Small bandwidth data refers to signals with narrow frequency ranges. These signals do not require a wide bandwidth for transmission. TDM is suitable for such signals because it allows multiple narrowband signals to be combined and transmitted over a single communication channel.
Combination of Slow Changing and Small Bandwidth Data
When the data to be transmitted is both slow changing and has a small bandwidth, TDM becomes particularly advantageous. It allows multiple slow-changing and narrowband signals to be efficiently combined and transmitted over a single communication channel.
Fast Changing and Wide Bandwidth Data
On the other hand, TDM is not suitable for fast-changing signals, such as high-speed data and video signals, as these signals require a high sampling rate and a wide bandwidth for accurate representation. TDM may not provide sufficient time slots or bandwidth allocation for such signals, leading to information loss and distortion.
Conclusion
In conclusion, TDM is used when the data to be transmitted is slow changing and has a small bandwidth. It allows multiple slow-changing and narrowband signals to be efficiently combined and transmitted over a single communication channel. However, it may not be suitable for fast-changing signals with wide bandwidth requirements.
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