It is a very common requirement to detect either positive edge, negative edge or both edges of a signal. And the circuit that can detect and generate a single cycle pulse is quite simple. In this post, we will discuss how we can detect positive edge, negative edge and both edges of a signal.
- Detect positive edge of a signal: Positive edge of a signal means that the current state of the signal is "1" and previous state is "0". And a pulse signal means that the output of the circuit is "1" for one cycle. So, we need a circuit which generates "1" as output when present state is "1" and previous state is "0". It generates "0" as output otherwise.
Thus, output = D(n-2)' & D(n-1)
The required implementation is shown in figure 1 below:
 |
| Figure 1: Detection of positive edge of signal |
- Detect negative edge of a signal: Negative edge of signal means that the current state of the signal is "0" and previous state is "0". So, we need a circuit which generates "1" as output when present state is "0" and previous state is "1". It generates "0" as output otherwise.
Thus, Neg_edge_detect = D(n-2) & D(n-1)'
The required implementation is shown in figure 2 below:
 |
| Figure 2: Detection of negative edge of signal |
- Detecting both positive and negative edges of the signal: Simply doing an "OR" operation of Pos_edge_detect and Neg_edge_detect signal will produce an output which is a single cycle pulse for any of the edge of incoming signal. The requirement for consecutive edges of incoming signal is to be at least 2 cycles apart otherwise, the output will not be pulse, but will be a continuous signal.
Any_edge_detect = Pos_edge_detect + Neg_edge_detect
The required implementation is shown in figure 3 below:
 |
| Figure 3: Detection of both positive and negative edges of signal |
The technique we discussed here delays the output by two cycles. Can you think of any other way to detect the edges of a signal which is more efficient?
Keep on working, great job!
ReplyDelete