Duty cycle degradation

In the post, we discussed about duty cycle variation of the clock source. However, this is not the only pain in half cycle timing paths. Along clock path also, duty cycle of the clock can degrade. This can effect timing of half cycle paths adversely. We will discuss this in some detail; and also discuss how to tackle this. 

How is there degradation in duty cycle of clock: In addition to source duty cycle variation, there can be assymmetry in rise delay vs fall delay of clock elements. For instance, a buffer may have nominal rise (0 -> 1) delay of 50 ns whereas 48 ns for fall delay (1 -> 0). So, if a clock pulse passes through it, it will eat a portion of this clock pulse as shown in figure 1 below. For more clarity, we have exaggerated the scenario with a fall delay of 30 ns.


There are a lot of delay elements in clock distribution networks (also called clock tree network) inside the SoC. So, this problem is bound to happen there. Let us say, clock path has 20 buffers, each having a rise delay 10 ps greater than fall delay. So, the high pulse will get shortened when the clock reaches its sink. See how the pulse gets shortened if there is asymmetry in rise vs fall delay of a delay element or logic gate in below figure.



Even if we assume that the delay element has rise delay equal to fall delay, still, there is possibility of duty cycle degradation. Normally, a buffer (or inverter) has a nominal delay with some delay variations (for instance, OCVs) to be taken into account. For instance, it may have a rise delay of 100 ps with OCV variation to be taken of 5%. So, depending upon the scenario, we need to take its delay as either 95 ps or 105 ps. Similarly, even if we say that fall delay is exactly equal to rise delay, even then because of OCV variations, fall delay to be taken into account will be different than rise delay. Let us suppose, there are 20 such buffers in clock path with an ideal clock source. Then, we will have uncertainty in arrival of both rise and fall edges. And the effect will be visible in timing paths' slack.


How duty cycle degradation impacts timing: Degradation in duty cycle impacts timing wherever both rising and falling edges of clock are involved. For instance, it will impact half cycle timing paths as well as minimum pulse width check. You can go through our post duty cycle of clock to have an idea of the impact.


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