Time borrowing in latches

What is time borrowing: Latches exhibit the property of being transparent when clock is asserted to a required value. In sequential designs, using latches can enhance performace of the design. This is possible due to time borrowing property of latches. We can define time borrowing in latches as follows:
Time borrowing is the property of a latch by virtue of which a path ending at a latch can borrow time from the next path in pipeline such that the overall time of the two paths remains the same. The time borrowed by the latch from next stage in pipeline is, then, subtracted from the next path's time.
The time borrowing property of latches is due to the fact that latches are level sensitive; hence, they can capture data over a range of times than at a single time, the entire duration of time over which they are transparent. If they capture data when they are transparent, the same point of time can launch the data for the next stage (of course, there is combinational delay from data pin of latch to output pin of latch).

Let us consider an example wherein a negative latch is placed between two positive edge-triggered registers for simplicity and ease of understanding. The schematic diagram for the same is shown in figure 1 below:


A latch placed between two registers. Tha path from regA to latch can borrow time from the path between latch and regB
Figure 1: Negative level-sensitive latch between two positive edge-triggered registers

Figure 2 below shows the clock waveform for all the three elements involved. We have labeled the clock edges for convenience. As is shown, latB is transparent during low phase of the clock. RegA and RegC (positive edge-triggered registers) can capture/launch data only at positive edge of clock; i.e., at Edge1, Edge3 or Edge5. LatB, on other hand, can capture and launch data at any instant of time between Edge2 and Edge3 or Edge4 and Edge5.


Clock waveforms for positive register negative latch positive flip-flop case
Figure 2: Clock waveforms

The time instant at which data is launched from LatB depends upon the time at which data launched from RegA has become stable at the input of latB. If the data launched at Edge1 from RegA gets stable before Edge2, it will get captured at Edge2 itself.  However, if the data is not able to get stable, even then, it will get captured. This time, as soon as the data gets stable, it will get captured. The latest instant of time this can happen is the latch closing edge (Edge3 here). One point here to be noted is that at whatever point data launches from LatB, it has to get captured at RegC at edge3. The more time latch takes to capture the data, it gets subtracted from the next path. The worst case setup check at latB is at edge2. However, latch can borrow time as needed. The maximum time borrowed, ideally, can be upto Edge3. Figure 3 below shows the setup and hold checks with and without time borrow for this case:

A latch can borrow time from next stage timing path.
Figure 3: Setup check with and without time borrow

The above example consisted of a negative level-sensitive latch. Similarly, a positive level-sensitive latch will also borrow time from the next stage, just the polarities will be different.

Also read:

2-input gates using 2:1 mux

Definition of a multiplexer: A 2^n-input mux has n select lines. It can be used to implement logic functions by implementing LUT (Look-Up Table) for that function. A 2-input mux can implement any 2-input function, a 4-input mux can implement any 3-input, an 8-input mux can implement any 4-input function, and so on. This property of muxes makes FPGAs implement programmable hardware with the help of LUT muxes. In this post, we will be discussing the implementation of 2-input AND, OR, NAND, NOR, XOR and XNOR gates using a 2-input mux.


2-input AND gate implementation using 2:1 mux: Figure 1 below shows the truth table of a 2-input AND gate. If we observe carefully, OUT equals '0' when A is '0'. And OUT follows B when A is '1'. So, if we connect A to the select pin of a 2:1 mux, AND gate will be implemented if we connect D0 to '0' and D1 to 'B'.

A 2-input AND gate has output '0' when either or both inputs is '0'. And output is '1' when both the inputs are '1'.
Figure 1: Truth table of AND gate
Figure 2 below shows the implementation of 2-input AND gate using a 2:1 multiplexer.

An AND gate can be implemented using a 2-input multiplexer by connected D0 input to '0' and D1 to B, SEL being connected to A. AND gate using mux, AND gate using 2x1 mux, 2-input AND gate using mux
Figure 2: Implementation of AND gate using a 2:1 mux



2-input NAND gate using 2:1 mux: Figure 3 below shows the truth table of a 2-input NAND gate. If we observe carefully, OUT equals '1' when A is '0'. Similarly, when A is '1', OUT is B'. So, if we connect SEL pin of mux to A, D0 pin of mux to '1' and D1 to B', then it will act as a NAND gate.

In a 2-input NAND gate, output is '0' when both inputs are '1', otherwise output is '1'
Figure 3: Truth table of 2-input NAND gate

Figure 4 below shows the implementation of a 2-input NAND gate using 2:1 mux.


A NAND gate can be implemented using a 2-input multiplexer, if we connect the select pin of the multiplexer to A, D0 to VDD and D1 to B' inputs. NAND gate using mux, NAND gate using 2x1 mux
Figure 4: Implementation of 2-input NAND gate using 2:1 mux

2-input OR gate using 2x1 mux: Figure 5 below shows the truth table for a 2-input OR gate. If we observe carefully, OUT equals B when A is '0'. Similarly, OUT is '1' (or A), when A is '1'. So, we can make a 2:1 mux act like a 2-input OR gate, if we connect D0 pin to B and D1 pin to A, with select connected to A.

In a 2-input OR gate, output is '1' when either or both of the inputs are '1'. Otherwise, output is '0'.
Figure 5: Truth table of 2-input OR gate

Figure 6 below shows the implementation of 2-input OR gate using a 2:1 multilpexer:


A 2-inputs multiplexer can be converted to an OR gate, if we connect the select pin of mux to A-input, D0 to B-input and D1 to VDD. OR gate using mux, OR gate using 2x1 mux
Figure 6: Implementation of 2-input OR gate using 2:1 mux


2-input NOR gate using 2x1 mux: Figure 7 below shows the truth table of a 2-input NOR gate. If we observe carefully, OUT equal B' when A is '0'. Similarly, OUT equals '0' when A is '1'. So, we can make a 2-input mux act like a 2-input NOR gate, if we connect SEL of mux to A, D0 to B' and D1 to '0'.

In a 2-input NOR gate, output equals '0' when either or both the inputs is '1'. Otherwise, output is '0'.
Figure 7: Truth table of 2-input NOR gate
Figure 8 shows the implementation of 2-input NOR gate using 2:1 mux.


NOR gate using mux, 2-input NOR gate using 2:1 mux, NOR gate using 2x1 mux
Figure 8: Implementation of 2-input NOR gate using 2x1 mux


2-input XNOR gate using 2x1 mux: Figure 9 below shows the truth table of a 2-input XNOR gate. If we observe carefully, OUT equals B' when A is '0' and equals B when A is '1'. So, a 2-input XNOR gate can be implemented from a 2x1 mux, if we connect SEL pin to A, D0 to B' and D1 to B.

In a 2-input XNOR gate, output equals '0' when exactly one of the inputs is '1', otherwise output is '1'.
Figure 9: Truth table of 2-input XNOR gate
The implementation of 2-input XNOR gate using a 2x1 mux is as shown in figure 10.
A 2-input XNOR gate can be realized using a 2:1 mux provided we connect the select to A-input, D0 to B' and D1 to B. XNOR gate using mux, XNOR gate using 2x1 mux, 2-input XNOR gate using mux
Figure 10: Implementation of 2-input XNOR gate using 2x1 mux


2-input XOR gate using 2x1 mux: Figure 11 shows the truth table for a 2-input XOR gate. If we observe carefully, OUT equals B when A is '0' and B' when A is '1'. So, a 2:1 mux can be used to implement 2-input XOR gate if we connect SEL to A, D0 to B and D1 to B'.

In a 2-input XNOR gate, output equals '1' when exactly one of the inputs is '1', otherwise output is '0'.
Figure 11: Truth table of 2-input XOR gate
Figure 12 shows the implementation of 2-input XOR gate using 2x1 mux.
A 2-input XNOR gate can be realized using a 2:1 mux provided we connect the select to A-input, D0 to B and D1 to B'. XOR gate using mux, 2-input XNOR gate using mux, XNOR gate using 2:1 mux
Implementation of 2-input XOR gate using 2x1 mux

NOT gate using 2:1 mux: Figure 13 shows the truth table for a NOT gate. The only inverting path in a multiplexer is from select to output. To implement NOT gate with the help of a mux, we just need to enable this inverting path. This will happen if we connect D0 to '1' and D1 to '0'.
Truth table of NOT gate
Figure 13: Truth table of NOT gate
Figure 14 shows the implementation of NOT gate using 2x1 mux:
NOT gate using 2-input mux, NOT gate using mux, NOT gate using multiplexer
Figure 14: Implementation of NOT gate using 2x1 mux