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TACTICAL (sentence-level): - Applied Gopen's issue-point positioning - Strengthened verb choices (active over passive where appropriate) - Reduced wordiness while maintaining technical precision - Improved topic-stress positioning for better flow - Tightened long sentences for readability OPERATIONAL (paragraph/section): - Smoothed transitions between paragraphs - Added explicit figure references where needed - Improved subsection transitions in formal methods section - Enhanced flow from theoretical to practical sections STRATEGIC (document-level): - Ensured each section clearly addresses its Heilmeier question - Improved consistency of Heilmeier framing across sections - Strengthened transitions between major sections - Verified alignment of outcomes with stated research questions
94 lines
4.5 KiB
TeX
94 lines
4.5 KiB
TeX
\section{Schedule, Milestones, and Deliverables}
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\textbf{How long will it take?} This research will be conducted over six trimesters (24 months) of full-time effort following the proposal defense in Spring 2026. The University of Pittsburgh Cyber Energy Center and NRC Fellowship provide all computational and experimental resources. The work progresses sequentially through three main research thrusts, culminating in integrated demonstration and validation.
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The first semester (Spring 2026) focuses on Thrust 1, translating startup
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procedures into formal temporal logic specifications using FRET. This
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establishes the foundation for automated synthesis by converting natural
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language procedures into machine-readable requirements. The second semester
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(Summer 2026) addresses Thrust 2, using Strix to synthesize the discrete
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automaton that defines mode-switching behavior. With the discrete structure
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established, the third semester (Fall 2026) develops the continuous controllers
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for each operational mode through Thrust 3, employing reachability analysis and
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barrier certificates to verify that each mode satisfies its transition
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requirements. Integration and validation occupy the remaining three semesters.
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Figure \ref{fig:gantt} shows the complete project schedule including research thrusts, major milestones, and planned publications.
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\begin{figure}[htbp]
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\centering
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\begin{ganttchart}[
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hgrid,
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vgrid={*{4}{draw=none}, dotted},
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x unit=0.4cm,
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y unit title=0.6cm,
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y unit chart=0.4cm,
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title/.append style={fill=gray!30},
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title height=1,
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bar/.append style={fill=blue!50},
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bar height=0.5,
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bar label font=\small,
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milestone/.append style={fill=red, shape=diamond},
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milestone height=0.5
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]{1}{24}
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% Timeline headers
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\gantttitle{2026}{12}
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\gantttitle{2027}{12} \\
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\gantttitle{Spring}{4}
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\gantttitle{Summer}{4}
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\gantttitle{Fall}{4}
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\gantttitle{Spring}{4}
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\gantttitle{Summer}{4}
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\gantttitle{Fall}{4} \\
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% Major thrusts
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\ganttbar{Thrust 1: Procedure Translation}{1}{5} \\
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\ganttbar{Thrust 2: Discrete Synthesis}{4}{10} \\
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\ganttbar{Thrust 3: Continuous Control}{9}{15} \\
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\ganttbar{Integration \& Simulation (TRL 4)}{13}{17} \\
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\ganttbar{Hardware-in-Loop Testing (TRL 5)}{16}{21} \\
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\ganttbar{Dissertation Writing}{18}{24} \\[grid]
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% Milestones row
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\ganttbar[bar/.append style={fill=orange!50}]{Milestones}{1}{24}
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\ganttmilestone{}{4}
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\ganttmilestone{}{8}
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\ganttmilestone{}{12}
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\ganttmilestone{}{16}
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\ganttmilestone{}{20}
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\ganttmilestone{}{24} \\
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% Publications row
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\ganttbar[bar/.append style={fill=green!50}]{Publications}{1}{24}
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\ganttmilestone{}{8}
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\ganttmilestone{}{16}
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\ganttmilestone{}{20}
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\end{ganttchart}
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\caption{Project schedule showing major research thrusts, milestones (orange row), and publications (green row). Red diamonds indicate completion points. Overlapping bars indicate parallel work where appropriate.}
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\label{fig:gantt}
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\end{figure}
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\subsection{Milestones and Deliverables}
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Six major milestones mark critical validation points throughout the research. M1
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(Month 4) confirms that startup procedures have been successfully translated to
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temporal logic using FRET with realizability analysis demonstrating consistent
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and complete specifications. M2 (Month 8) validates computational tractability
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by demonstrating that Strix can synthesize a complete discrete automaton from
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the formalized specifications. This milestone delivers a conference paper
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submission to NPIC\&HMIT documenting the procedure-to-specification translation
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methodology. M3 (Month 12) achieves TRL 3 by proving that continuous controllers
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can be designed and verified to satisfy discrete transition requirements. This
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milestone delivers an internal technical report demonstrating component-level
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verification. M4 (Month 16) achieves TRL 4 through integrated simulation
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demonstrating that component-level correctness composes to system-level
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correctness. This milestone delivers a journal paper submission to IEEE
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Transactions on Automatic Control presenting the complete hybrid synthesis
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methodology. M5 (Month 20) achieves TRL 5 by demonstrating practical
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implementability on industrial hardware. This milestone delivers a conference
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paper submission to NPIC\&HMIT or CDC documenting hardware implementation and
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experimental validation. M6 (Month 24) completes the dissertation documenting
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the entire methodology, experimental results, and research contributions.
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