#corecomponents

Quality Management System for Quantum Technology

Quantum Technology Quality Management System guides responsible innovation and development in the fast-growing field of quantum technology. The most promising technique for regulating quantum technologies in their early stages is this framework, sponsored by a global community of legal and policy experts and prioritising voluntary international norms over superfluous government regulation.

Standards-First Approach Required

Computing, telecommunications, sensing, metrology, and other quantum technologies are commercialising swiftly. This technology may impact national security, economic upheaval, medicinal discovery, and code-breaking. Despite rapid technological innovation, policy formation has delayed, posing risk management and governance challenges.

Traditional regulatory regimes may be too slow, restrictive, or fragmented to address global, fluid quantum innovation. Standards are more adaptive, develop faster, and are applicable across borders. The researchers said standards are voluntary, consensus-based systems. Without legal restrictions, they set technical and quality standards to guide innovation and international cooperation. A “standards-first” strategy allows governance structures to quickly adapt to technological advances, reward compliance rather than requirements, and reconcile conflicting global perspectives.

QT-QMS main parts and scope

The proposed Quantum Technology Quality Management System should be thorough and built by ISO/IEC. Many factors are considered in its design, including:

Examples of technological standards include encryption protocol definitions and quantum computing terminologies.

QMS frameworks control technology development, maintenance, and auditing.

Implications for ethics, law, society, and policy Ethical, Legal, Social, and Policy Implications. QT-QMS would combine these critical variables throughout the technology lifecycle, from conception to testing, deployment, and risk management.

The study distinguishes technical standards and QMS as the framework. Early on, most challenges are technical rather than related to real-world applications, hence the goal is to create a quantum industry template.

The role of ISOs

International standards organisations design quantum governance systems. The IEEE, IEC, and ISO are key stakeholders in this process. These groups are creating risk management, security, interoperability, and quantum language frameworks.

JTC3 studies concern quantum resource simulation, machine learning datasets, and energy efficiency in quantum computing. Like the U.S. National Institute of Standards and Technology (NIST), which is finalising post-quantum encryption standards to withstand quantum computer attacks, standards can address security vulnerabilities without legislative delays.

Integration with Standards

International standards are used in the planned QT-QMS to enable an integrated and cohesive system. These standards could be integrated into QT-QMS:

Information-security ISO 27001. Risk management ISO 27005 AI governance ISO 42001. The operational framework and common language of an integrated system are standards, linking innovation to responsibility and trust. Standards by reference help regulators with third-party certification, future compliance, and audit standardisation across jurisdictions.

Model QT-QMS benefits This “standards-first” approach to Quantum Technology Quality Management System has several advantages:

In quantum research, standards reduce risk and provide common technical vocabulary, testing methods, interoperability guidelines, and benchmarks, fostering innovation and global cooperation. They coordinate, prevent fragmentation, and help governments, corporations, and researchers achieve goals.

This is significant in a field where geopolitical competition may hinder consistent regulation since the standards process may sidestep these disputes and focus on agreement.

Restrictions and Future Regulation

For all their benefits, experts warn that standards are not a cure-all. Powerful players may affect technological standard-setting, causing anti-competitive behaviour or lock-in. Protections for legitimacy, inclusion, and fair participation in international standards procedures may reflect geopolitical disputes.

Open Quantum Safe (OQS) is an open-source initiative that promotes quantum-resistant cryptography. It is a member of the Linux Foundation and the Post-Quantum Cryptography Alliance.

A full explanation of Open Quantum Safe:

Purpose and Goal

Open Quantum Safe develops and tests quantum-resistant encryption. The main goal is to help businesses transition to a quantum-safe future by providing resources to develop and test new cryptographic algorithms. It provides quantum-resistant cryptography prototype software.

Research by the project team and others is sponsored.

History

In 2014, Michele Mosca and Douglas Stebila founded the scientific OQS initiative.

Initial goals included testing and prototyping quantum-resistant algorithms.

As post-quantum cryptography developed and the NIST PQC standardisation process began, Open Quantum Safe refocused on developing a production-track codebase for standardised algorithms while supporting novel algorithm research.

Open Quantum Safe joined the Linux Foundation in January 2024.

Architecture and Core Parts

Open Quantum Safe has two main parts:

Liboqs is an open-source C library for quantum-resistant cryptography. It is central to the OQS project. KEMs and digital signature systems are quantum-resistant cryptographic methods used in liboqs. It supports x86-64, ARM32v7, and ARM64v8 and builds on Windows, macOS, and Linux. Wrappers are available for C++, Go, Java,.Net, Python, and Rust. The Open Quantum Safe team creates prototypes that integrate liboqs into popular applications and protocols. This lets researchers and developers test the performance of novel algorithms in real-world contexts. TLS, SSH, X.509, and CMS/S/MIME are examples of integrations. Demo connections exist for Apache, nginx, haproxy, curl, and Chromium. “Crypto-agile” OQS's architecture is “crypto-agile,” making cryptographic algorithm switching easy. The PQC scene is evolving, thus this is crucial. Combining new post-quantum algorithms with RSA and ECC will create a hybrid strategy that manages transition risk.

Algorithms for Quantum Resistance

Encouraged In the Open Quantum Safe framework, post-quantum cryptography solutions based on “hard problems” that classical and quantum computers struggle to solve are developed. The following are:

CRYSTALS-Kyber (a KEM) and CRYSTALS-Dilithium (a digital signature scheme) were two of the first algorithms NIST standardised. Other supported lattice-based algorithms are FrodoKEM and NTRU-Prime.

SPHINCS+ and LMS/XMSS/HSS are hash-based cryptography algorithms. Though they have larger signatures or fewer key pair usage, these are likely secure.

HQC and Classic McEliece are code-based cryptography techniques.

Additional cryptography families like isogeny-based and multivariate-based are examined.

Some of the other specific algorithms mentioned include BIKE, CROSS, MAYO, ML-DSA, ML-KEM, and SNOVA.

Advantages

Future-Proofing: Open Quantum Safe prepares enterprises for quantum computers that can crack public-key encryption.

Open Source: This collaborative initiative promotes community code audits and openness.

Crypto-Agility: PQC's modular architecture makes algorithm conversion easy as requirements change.

Prototyping: Before standardisation and implementation, researchers and developers can test novel algorithms and understand their performance implications.

Drawbacks and Issues

Performance Overhead: Many post-quantum techniques are computationally demanding and have higher key sizes and signatures than conventional algorithms, affecting network performance and storage.

Lack of Standardisation: NIST has selected various algorithms for standardisation, but the process is ongoing. Because new algorithms have not been as carefully tested as RSA or ECC, new weaknesses may be uncovered.

“Harvest Now, Decrypt Later” Threat: Without a quantum computer to overcome encryption, sensitive data could be collected and stored, requiring an urgent change.

Migration complexity: Switching to new cryptographic standards for large, complex infrastructures requires careful planning, a lot of money, and a skilled team.

Applications

Anyone using public-key cryptography can utilise Open Quantum Safe. Useful regions include:

TLS encryption of email, web traffic, and other network communications using quantum-resistant methods.

Software Updates: Authenticating firmware and software upgrades with quantum-resistant digital signatures.

Defending IoT communications and low-power devices.

Defending blockchain and digital currency cryptography from quantum assaults.

Shown and integrated: OpenVPN, Chromium, curl, links, nginx, Apache httpd.

Develop and Community

All development happens in GitHub repositories. Project welcomes new contributors.

The Linux Foundation Mentorship program offers mentorships.

There are many public, private, business, and academic supporters of the effort. Important industry partners include Microsoft, IBM, and Amazon Web Services.

Modifications include liboqs, oqs-provider, and Rust, Java, C++, Go, and Python bindings. Liboq security assessments are public.

Benchmarking, Research

TLS, memory, and core algorithm benchmarks are available from Open Quantum Safe.

DESIGN SYSTEM

We were introduced to a new objective in relation to our brief, timeline and campaign awareness. We are currently still in the research + mapping process. Down below are a few notes I took as Meighan began explaining to us specifically about the design systems, and it’s components, series of outputs, etc. Oh, I also forgot to mention one more core component, Photography.