160 lines
6.3 KiB
TeX
160 lines
6.3 KiB
TeX
\subsection{Parallel bus}
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The core part of the hardware is the interface between the microprocessor and
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the hardware peripherals. This bus is delivering data in parallel and is
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therefore named the ``parallel bus``. This bus has 3 different sub-parts:
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\begin{enumerate}
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\item{The address bus}
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\item{The data bus}
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\item{The control bus}
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\end{enumerate}
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This split is common in many computer architectures and bus systems used by
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various microprocessor manufacturers. In figure \ref{fig:atari_pbi} the
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layout of the Atari Parallel Bus Interface is shown as used on the Atari 800XL.
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\begin{figure}[H]
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\includegraphics[width=\textwidth, angle=0]{pics/atari_pbi}
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\caption{Atari PBI Pinout;Source: \url{https://www.atarimagazines.com}}
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\label{fig:atari_pbi}
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\end{figure}
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\paragraph{System Bus}
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In some architectures the backbone parallel bus consisting of data- address- and
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control bus is called the system bus. The system bus even has its own wikipedia
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article \footnote{\url{https://en.wikipedia.org/wiki/System_bus}} and the
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picture seen in
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figure \ref{fig:sysbus}, which has been taken from this wikipedia article, even
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shows the exact same parts. However the origin of this term could not be
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determined and its use was the most common when describing the interface between
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the fabric of the CPU with external parts via this interface on a motherboard,
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which ran on system clock speed and was synchronized with the processor.
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The term parallel bus was chosen for this thesis because the bus runs on an
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independant clock speed and only interacts with the processor asynchronous to
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its clock. The term front side bus would be more fitting but not used because of
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its affiliation with intel products.
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\begin{figure}[H]
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\includesvg[width=\textwidth, angle=0]{pics/sysbus}
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\caption{System bus structural diagram; Source: \url{https://en.wikipedia.org/}}
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\label{fig:sysbus}
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\end{figure}
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\subsubsection{Address Bus}
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The address bus contains the nescessary data lines for addressing the individual
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registers of the Serial connection and the UART. On any modern system this bus
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is from 16 to 64 bits wide. For our implementation the bus size was chosen to
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be 8 bit, which is multiple times the amount of needed address space, but
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is the smallest addressable unit on most microcontroller architectures and
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therefore easy to program with. The address bus is unidirectional.
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\subsubsection{Data Bus}
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The data bus contains the actual data to be stored to and read from registers.
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The data bus is as well on most systems a multiple of 16 bits wide, but for the
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same reasons as the data bus is shrunk down in our case to 8 bits. The data
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bus is bidirectional.
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\subsubsection{Control Bus}
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Control bus is a term which referes to any control lines (such as read and write
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lines or clock lines) which are neither address nor data bus. The control bus
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in our case is 5 bits wide and consists of:
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\begin{table}[H]
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\centering
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\begin{tabular}{| c | r |}
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\hline
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\textbf{Signal} & \textbf{Description}\\
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\hline
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\hline
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$MR$ & Master Reset \\
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\hline
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$\lnot WR$ & Write Not\\
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\hline
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$\lnot RD$ & Read Not \\
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\hline
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$\lnot MS1$ & Module Select 1 Not \\
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\hline
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$\lnot MS2$ & Module Select2 Not\\
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\hline
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\end{tabular}
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\caption{Signals on the control bus}
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\label{tab:ctrl_bus}
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\end{table}
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\paragraph{Master Reset}
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A high level on the $MR$ lane signals to the peripherals, that a reset of all
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registers and states should occure. This is needed for the serial console and
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the DAC.
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\paragraph{Write Not}
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A low level on the $\lnot WR$ lane signals the corresponding modules, that the
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data on
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the data bus should be written to the register on the address specified from the
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address bus.
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\paragraph{Read Not}
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A low level on the $\lnot RD$ lane signals the corresponding modules, that the
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data
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from the register specified by the address on the address bus should be written
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to the data bus.
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\paragraph{Module Select 1 and 2 Not}
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A low level on one of these lines signals the corresponding module, that the
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data on address data and the control lines is meant for it.
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\paragraph{Sepearation of $\lnot RD$/$\lnot WR$ and$\lnot MS1$/$\lnot MS2$}
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The Read Not and Write Not lines could be combined into one line $\lnot RD/WR$.
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The same can be done for the Module Select lanes. In both cases this would
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have made wiring inside the finished modules more difficult and if both were
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combined the bus would not be able to not perform an action at any given
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point in time. Therefore these signals have not been combined.
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\subsection{Von Neumann Archtiecture}
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The term ``von Neumann architecture`` refers to a type of computer architecture
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which referres to almost any modern computer system. It describes the in this
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thesis used Human input and output parts and the general workings of modern
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processors with the ALU\footnote{ALU...arithmetic logic unit} or the CA
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\footnote{CA...Central Arithmetic Part} as well as means to interface with its
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operator\cite{neumann}.
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In his thesis ``First Draft of a Report on the EDVAC`` he writes about human
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input:
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\vspace{1cm}
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``Once these instructions are given to the device, it must be able to carry them out completely and
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without any need for further intelligent human intervention. At the end of the required operations
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the device must record the results again in one of the forms referred to above.``\cite[p.7]{neumann}
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\vspace{1cm}
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This can be applied to the hardware implemented in this thesis, as well as
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other general computing systems. The EDVAC, which his thesis referres to, was a
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computer developed for military purposes. Much like the EDVAC, the CPU in this
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thesis is responsible for arithemtic operations and code interpetation. The
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peripherals are what is referred to as the input and output devices in his
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report. Though the for examples used ATMega2650 utilizes a harvard architecture
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``In order to maximize performance and parallellism``\cite[p.11]{atmega2560} the
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more general descriptions of computational operations still apply to this
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thesis. The differences between a harvard architecture and a von neumann
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architecture are shown in figure \ref{fig:harvard_neumann}
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\begin{figure}[H]
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\includesvg[width=.5\textwidth, angle=0]{pics/harvard}
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\includesvg[width=.5\textwidth, angle=0]{pics/neumann}
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\caption{Harvard(left) vs Von-Neumann architecture(right);\\
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Source: \url{https://en.wikipedia.org/}}
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\label{fig:harvard_neumann}
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\end{figure}
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