Update TODOs.
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final/report.tex
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final/report.tex
@ -4,6 +4,8 @@
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\usepackage{amsmath}
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\usepackage{hyperref}
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\usepackage{xcolor}
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\usepackage{caption}
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\usepackage{subcaption}
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\definecolor{link}{HTML}{006275}
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\hypersetup{
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colorlinks,
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@ -45,7 +47,7 @@ changes:
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\begin{itemize}
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\item I added \textbf{additional precharge transistors} along the column, a total of 4.
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Each was sized at $5\lambda$, much like the SRAM transistors themselves. When the clock
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Each was sized at $10\lambda$, much like the SRAM transistors themselves. When the clock
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was low, these PMOS transistors became transparent, and helped precharge the bitlines faster.
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Doing so helped avid hysteresis. However, this did not help with writing during high clock,
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so...
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@ -57,11 +59,21 @@ changes:
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configuration, I did not place it in the middle of the column, as that would needlessly
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increase the length of the wires.
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\end{itemize}
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This led to the configuration shown in Figure \ref{fig:top-design}. To simulate this design, I placed
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a memory cell at the very top of my column, which is the furthest spot from both the read and write
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circuit. I also split the wire into 4 equally-sized fragments, each with resistance $\frac{R}{4}$ and
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capacitance $\frac{C}{4}$. Between each fragment, I added the aforementioned $5\lambda$ precharge
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%
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This led to the configuration shown in Figure \ref{fig:top-design}. To simulate this design, I \textbf{tested three configurations}:
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\begin{enumerate}
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\item A memory cell at the very top of my column, which is the furthest spot from both the read and write.
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This is the simulation in the figure.
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\item A memory cell in the middle of my column, in the same place as the write block. Since the write block
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has brief ``false starts'', this test was to ensure that the read block can still pick up data
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despite the write block's misfires.
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\item A memory cell at the very bottom of my column. This area has additional capacitance from the read block;
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it thus takes longer to charge up, and tends to be the first spot where writes fail.
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circuit.
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%
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\end{enumerate}
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I also split the wire into 4 equally-sized fragments, each with resistance $\frac{R}{4}$ and
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capacitance $\frac{C}{4}$. Between each fragment, I added the aforementioned $10\lambda$ precharge
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transistors, as well as 16 always-off $5\lambda$ transistors, which simulated the remaining memory cells.
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I also placed \textsc{Din}, \textsc{Ad0}, and \textsc{Rwt} behind the default-sized flip-flops
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attached to the clock to simulate something like a pipeline stage. My overall design is shown
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@ -89,12 +101,7 @@ of length to this number, to a total of roughly $2200\lambda$.
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\pagebreak
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\section{Performance Results}
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I was able to clock my design at 1.38ns. There is a caveat to this clock speed: my \textsc{Bt} and
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\textsc{Bf} lines are not pulled all the way to \textsc{Gnd} when they are written low. This
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doesn't seem to be a problem - it's sufficient to flip the furthest cell in the design in
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every situation I've tested. However, from what I hear, this was discouraged during one of
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the office hours (which I was unable to attend). With the constraint of pulling the wires
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all the way down, my design can operate at around 2.1ns.
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I was able to clock my design at $1.9\textit{ns}$.
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%
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Two factors lead to these upper limits.
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%
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@ -116,7 +123,7 @@ Two factors lead to these upper limits.
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\section{Components}
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\subsection{Decoder}
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\subsubsection{In My Own Words}
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The decoder in this design is exact same one as we were given in lecture.
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The decoder in this design is \textit{almost} the exact same one as we were given in lecture.
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It computes all combinations of two consecutive bits using a \textsc{Nand} gate; for
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each combination, there are 4 adjacent two-bit combinations,
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leading to a 4 \textsc{Nor} gates connected to each \textsc{Nand}. There are now
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@ -127,6 +134,20 @@ results in 256 unique \textsc{Wl} wires. Finally, these need to be attached
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to the clock, so that cells aren't open randomly. This is done using an \textsc{And}
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gate (a \textsc{Nand} followed by an inverter).
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I adjusted this design to account for the address signals that need to be fed
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into the write blocks. Which of the read/write columns is triggered
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depends on the upper two bits of the address (since we have 4 columns). I modeled
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this by increasing the fanout on the first \textsc{Nand} gate from 1 to 4.
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This is pessimistic; each 2-bit combination would only feed into one write block,
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whose trigger gate is normally sized.
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\begin{figure}[h]
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\centering
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\includegraphics[width=\linewidth]{decoder.png}
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\caption{Decoder model used in project.}
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\label{fig:decoder}
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\end{figure}
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% TODO: Domino logic
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% TODO: More inverters?
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@ -151,7 +172,7 @@ on the two \textsc{Nand3} gates was easy to understand and build, but was less
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sensitive, and tended to behave strangely under pressure. This led to difficulties
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with debugging (the output would, for instance, flip completely at certain
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wire widths), and was seemingly random. Instead, I used
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an \textbf{improved latch-based sense amplifier design} from . % TODO: cite
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an \textbf{improved latch-based sense amplifier design} from \cite{210039}. % TODO: cite
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The design I used is shown in Figure \ref{fig:latch-amp}.
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I left it sized at $40\lambda$, since larger amplifiers seem to take longer
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to trigger and exit metastability.
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@ -163,9 +184,32 @@ the initial clock. Thus, if a write occurred during a previous cycle, the write
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activate for a short period of time before the read block does. The memory cell
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will overpower this initial misfire\footnote{According to my additional simulations, this is true even when the memory cell is close to the write block.}, but in this case, both \textsc{Bt} and \textsc{Bf}
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will be below \textsc{Vdd}. The ``improved sense amplifier'' seems to handle this
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case better than the one based on two \textsc{Nand} gates. I think that both Reed and
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Graham experienced this occurrence -- they seemed to post very similar waveforms
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to the community Discord group chat.
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case better than the one based on two \textsc{Nand} gates.
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The latch-induced delay in \textsc{Rwt} also causes a strange \textsc{Trigger} signal during write operations
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directly following read operations. The trigger signal initialy activates, putting the sense
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amplifier into metastability; however, the correct \textsc{Rwt} value arrives before the
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sense amp's outputs are compromised. If this became a problem, I would add an additional,
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delayed clock signal \emph{after} the sense amplifier, and use an \textsc{And} gate
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to delay the read block's output.
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\begin{figure}[h]
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\centering
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\begin{subfigure}{.5\textwidth}
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\centering
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\includegraphics[width=.7\linewidth]{amp.png}
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\caption{The latch-based sense amplifier from \cite{210039}.}
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\label{fig:latch-amp}
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\end{subfigure}%
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\begin{subfigure}{.5\textwidth}
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\centering
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\includegraphics[width=.8\linewidth]{read_select.png}
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\caption{The block gathering signals from the four columns.}
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\label{fig:read-collect}
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\end{subfigure}
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\caption{Read block schematics}
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\label{fig:read}
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\end{figure}
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\pagebreak
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\subsection{Write Block}
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@ -173,8 +217,8 @@ to the community Discord group chat.
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The write block converts a ``data in'', or \textsc{Din}, signal
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into a one-hot representation. It does so by pulling one of the bitlines high, and the other
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low. Once the memory cell connects to the bitlines, it takes on the charge provided by the
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write block, and is therefore overwritten. In my design, two PMOS transistor for each bitline
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are used to pull down; one of the transistors is triggered by \textsc{Din} signal (which wire
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write block, and is therefore overwritten. In my design, two PMOS transistors for each bitline
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are used to pull down; one of the transistors is triggered by the \textsc{Din} signal (which wire
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we pull down depends on the signal itself!), and the other by a combination of the clock
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and \textsc{Rwt} (we don't want to touch the wires when reading!).
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@ -194,7 +238,9 @@ time is spent reading the wires, the memory cell in question is able to graduall
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of charge on one of these wires. Since the original, \textsc{Nand}-based sense amplifier required
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all inputs to be high to properly function, this led to it eventually ``flipping'' and producing
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the wrong output. This was only an issue above $5\textit{ns}$, and only with the original sense amplifier
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design, though.
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design, though. I think that both Reed and
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Graham experienced this occurrence -- they seemed to post very similar waveforms
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to the community Discord group chat.
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One thing to note about the write block is that its \textbf{clock input is deliberately delayed} compared
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to the ``actual'' clock. This is because of an issue with \textsc{Din}. Since this
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@ -202,12 +248,19 @@ input is behind a latch, it takes around $300\textit{ps}$ to arrive after the ri
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edge. If the previous value of \textsc{Din} was different than its current one, the write
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block will start writing the wrong value. This will typically mean that the block cannot properly
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perform the write. The delay on the clock input serves to mitigate this issue, by giving more
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time for \textbf{Din} to settle before starting to write. To compensate for this delay, I sized
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time for \textsc{Din} to settle before starting to write. To compensate for this delay, I sized
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the write block's pull down transistors quite large ($100\lambda$), so that they can pull
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the wire down, even starting $300\textit{ps}$ into the cycle. This is why the ``clock'' input
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in my diagrams is colored black, unlike every other clocked component. The delay is achieved
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by 6 sequenced inverters, two of which are sized 10x larger than the rest.
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\begin{figure}[h]
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\centering
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\includegraphics[width=0.65\linewidth]{write.png}
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\caption{Write block used in this project.}
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\label{fig:write}
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\end{figure}
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\pagebreak
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\subsection{Memory Cell}
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\subsubsection{In My Own Words}
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@ -250,4 +303,58 @@ above - it becomes nigh impossible to wire further \textsc{Wl} lines through eac
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unless the decoder is split into bits, in which case the width of the entire assembly drastically increases,
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slowing down all signals.
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\begin{figure}[h]
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\centering
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\includegraphics[width=0.5\linewidth]{layout_single.png}
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\caption{Electric layout for a single cell.}
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\label{fig:layout-cell}
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\end{figure}
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\pagebreak
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My basic cell is shown in Figure \ref{fig:layout-cell}. The arrayed version (in Figure \ref{fig:layout-arrayed})
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merits additional explanation. In my earlier description of the overall design, I mentioned
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that I have precharge PMOS transistors. I have integrated these into my layout to accurately model
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my design. I also made them $10\lambda$ wide, since this is, at the time of writing,
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the size of my 4 precharge transistors. In the bird's eye view (Figure \ref{fig:layout-arrayed-far}),
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three things can be observed:
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\begin{itemize}
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\item \textit{Additional vertical line:} This line represents the clock signal,
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which must be fed to the precharge transistors. In the full design, there would
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be 5 clock lines (3 shared, and 2 on either side).
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\item \textit{``Empty'' space between nodes:} I left this space because I was not sure
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how wide I would end up making my \textsc{Bt} and \textsc{Bf} wires. I have measured
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the distance to ensure that the design will remain DRC clean with up to \textbf{$8\lambda$-wide bitlines}.
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This appears to be a sweet spot for my design, anyway.
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\item \textit{Moved well contacts:} I have moved my well contacts to the region between
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two columns. By extending the N- and P-wells to this area, I was able to
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share a single contact between two cells, leaving room for prechare transistors
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on both sides of the cell. This was partially inspired by Reed's compact cell design,
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which shared a single contact between two cells\footnote{I am operating based on your
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comment that well contacts for every cell are significantly overkill.}.
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\end{itemize}
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Figure \ref{fig:layout-arrayed-close} shows a closer view of the design. Due to the additional
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space incurred, an entire column is approximately $100\lambda$ wide.
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\begin{figure}[h]
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\centering
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\begin{subfigure}{.5\textwidth}
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\centering
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\includegraphics[width=.7\linewidth]{layout_arrayed.png}
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\caption{Bird's eye view of the arrayed SRAM cells.}
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\label{fig:layout-arrayed-far}
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\end{subfigure}%
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\begin{subfigure}{.5\textwidth}
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\centering
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\includegraphics[width=.8\linewidth]{layout_arrayed_closeup.png}
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\caption{Close up from arrayed SRAM cells.}
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\label{fig:layout-arrayed-close}
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\end{subfigure}
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\caption{Read block schematics}
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\label{fig:layout-arrayed}
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\end{figure}
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\pagebreak
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\bibliographystyle{unsrt}
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\bibliography{bibliography}
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\end{document}
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