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DTSTART:19700308T020000
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DTSTAMP:20230124T171526Z
LOCATION:C140-142
DTSTART;TZID=America/Chicago:20221113T092000
DTEND;TZID=America/Chicago:20221113T094000
UID:submissions.supercomputing.org_SC22_sess423_ws_qcs107@linklings.com
SUMMARY:Automated Quantum Memory Compilation with Improved Dynamic Range
DESCRIPTION:Workshop\n\nAutomated Quantum Memory Compilation with Improved
  Dynamic Range\n\nSinha, Henderson, Henderson, Thornton\n\nEmerging quantu
 m algorithms that process data require that classical input data be repres
 ented as a quantum state.  These data-processing algorithms often follow t
 he gate model of quantum computing---which requires qubits to be initializ
 ed to a basis state, typically |0> ---and thus often employ state generati
 on circuits to transform the initialized basis state to a data-representat
 ion state.  There are many ways to encode classical data in a qubit, and t
 he oft-applied approach of basis encoding does not allow optimization to t
 he extent that other variants do.  In this work, we thus consider automati
 c synthesis of addressable, quantum read-only memory (QROM) circuits, whic
 h act as data-encoding state-generation circuits. We investigate three dat
 a encoding approaches, one of which we introduce to provide improved dynam
 ic range and precision.  We present experimental results that compare thes
 e encoding methods for QROM synthesis to better understand the implication
 s of and applications for each.\n\nSession Format: Recorded\n\nTag: Quantu
 m Computing\n\nRegistration Category: Workshop Reg Pass
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