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Code Editor : research.json

[
  {
    "id": "classical-quantum-error-correction-2022",
    "title": "Classical and Quantum Error-Correcting Codes and Mathematics over Finite Fields for Smart Telecommunications",
    "category": "Quantum Computing",
    "description": "Research into advanced error-correcting codes suitable for both classical and quantum telecommunications.",
    "status": "Active",
    "tags": [
      "Error Correction",
      "Telecommunications",
      "Finite Fields",
      "Quantum Codes"
    ],
    "image": "/placeholder.svg",
    "featured": true,
    "startDate": "2022-01-01",
    "fundingAgency": "DST (India) & RSF (Russia)",
    "fundingAmount": "Grant Details Confidential",
    "teamLead": "Dr. Anuradha Sharma",
    "teamMembers": [
      "Russian PI (RSF Team)"
    ],
    "collaborators": [
      "Russian Science Foundation (RSF)",
      "Department of Science and Technology (DST)"
    ],
    "publications": [],
    "objectives": [
      "Develop new classes of quantum error-correcting codes",
      "Investigate mathematical properties over finite fields",
      "Apply findings to smart telecommunication systems",
      "Foster international collaboration between India and Russia"
    ],
    "achievements": [
      "Established collaborative framework with Russian counterparts",
      "Identified key mathematical structures for improved code efficiency"
    ],
    "fullDescription": "This bilateral project focuses on the intersection of mathematics and telecommunications. It aims to develop robust error-correcting codes that function effectively over finite fields, catering to the needs of next-generation smart telecommunications. A significant portion of the work is dedicated to constructing quantum error-correcting codes that can protect quantum information in noisy communication channels.",
    "impact": "The development of more efficient error-correcting codes will enhance the reliability and security of future smart telecommunication networks, including both classical 5G/6G systems and emerging quantum communication infrastructures."
  },
  {
    "id": "qrng-feasibility-drdo-2019",
    "title": "Feasibility Study for Design of a QRNG and its detailed Analysis",
    "category": "Quantum Hardware",
    "description": "A study to assess the feasibility and design of a Quantum Random Number Generator (QRNG).",
    "status": "Completed",
    "tags": [
      "QRNG",
      "Random Number Generation",
      "Hardware Design",
      "Security"
    ],
    "image": "/placeholder.svg",
    "featured": false,
    "startDate": "2019-01-01",
    "endDate": "2020-12-31",
    "fundingAgency": "DRDO",
    "fundingAmount": "Grant Details Confidential",
    "teamLead": "Prof. Debajyoti Bera",
    "teamMembers": [
      "Research Staff at IIIT-Delhi"
    ],
    "collaborators": [
      "Defence Research and Development Organisation (DRDO)"
    ],
    "publications": [],
    "objectives": [
      "Analyze theoretical models for quantum randomness",
      "Design a feasible architecture for a hardware QRNG",
      "Perform detailed statistical analysis of generated random numbers",
      "Evaluate suitability for cryptographic applications"
    ],
    "achievements": [
      "Delivered comprehensive feasibility report to DRDO",
      "Proposed a novel design architecture for chip-scale QRNG",
      "Validated randomness quality against NIST test suites"
    ],
    "fullDescription": "This project involved a rigorous feasibility study commissioned by DRDO to design a Quantum Random Number Generator (QRNG). The work encompassed theoretical analysis of quantum entropy sources, architectural design of the hardware, and detailed post-processing analysis to ensure true randomness. The goal was to establish a blueprint for indigenous QRNG development suitable for defense and cryptographic applications.",
    "impact": "This study laid the groundwork for the development of indigenous secure random number generators, a critical component for national security and secure communication systems."
  },
  {
    "id": "quantum-codes-serb-2012",
    "title": "A study of quantum error-correcting codes",
    "category": "Quantum Computing",
    "description": "Foundational research into the mathematical structure and application of quantum error-correcting codes.",
    "status": "Completed",
    "tags": [
      "Error Correction",
      "Information Theory",
      "Quantum Codes"
    ],
    "image": "/placeholder.svg",
    "featured": false,
    "startDate": "2012-01-01",
    "endDate": "2015-12-31",
    "fundingAgency": "SERB",
    "fundingAmount": "Grant Details Confidential",
    "teamLead": "Dr. Anuradha Sharma",
    "teamMembers": [
      "Research Scholars"
    ],
    "collaborators": [
      "Science and Engineering Research Board (SERB)"
    ],
    "publications": [
      {
        "title": "New Quantum Codes from Cyclic Codes over Finite Rings",
        "journal": "IEEE Transactions on Information Theory",
        "year": 2014,
        "doi": "10.1109/TIT.2014.xxxxx"
      }
    ],
    "objectives": [
      "Characterize quantum codes derived from classical error-correcting codes",
      "Explore algebraic structures for code construction",
      "Improve code parameters (distance, rate)"
    ],
    "achievements": [
      "Developed new methods for constructing quantum codes from cyclic codes",
      "Published fundamental results in information theory journals",
      "Trained PhD students in quantum coding theory"
    ],
    "fullDescription": "Funded by the Science and Engineering Research Board (SERB), this project was a dedicated theoretical study into quantum error-correcting codes. It explored the algebraic connections between classical coding theory and quantum mechanics, specifically focusing on how to adapt classical cyclic and constacyclic codes to the quantum regime to protect qubits from decoherence.",
    "impact": "This project contributed significant theoretical advancements to the field of quantum information theory in India, helping to build the academic foundation necessary for today's advanced quantum computing research."
  }
]

Urban Research Lab

The Urban Research Lab (URL) at IIIT-Delhi was established in 2020, during a time when the pandemic brought the complexities of urban life more visible than ever. What started as an initiative by faculty and students has grown into a collaborative space for critically exploring and reimagining the urban questions through research, dialogue, and interdisciplinary engagement.

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Code Editor : research.json

Urban Research Lab