Dell Uses IBM Qiskit Runtime for Scalable Quantum Research

Analysis of Classical-Quantum Hybrid Computing

Dell Technologies Platform Models Quantum Applications with IBM Qiskit Runtime Emulator

Dell must exponentially increase compute capacity through a variety of distributed, diverse computing architectures that work together as a system, including quantum computing, to meet the demands of today's digital economy's growing data.

Quantum computation can accelerate simulation, optimisation, and machine learning. IT teams worldwide are investigating how quantum computing will effect operations in the future. There is a prevalent misperception that the quantum computer will replace all conventional computing and can only be accessed locally or remotely via a physical quantum device.

The system can now recreate key quantum environment features using classical resources. IT executives interested in learning more and those who have begun and want to enhance their algorithms may now access the technology. Emulators simulate both quantum and classical features of a quantum system, while simulators just simulate quantum aspects.

Dell Technologies tested a hybrid emulation platform employing the Dell PowerEdge R740xd and IBM's open-source quantum computer containerised service Qiskit Runtime. The platform lets users locally recreate Qiskit Runtime and test quantum applications via an emulator.

IBM's Vice President of Quantum Jay Gambetta said, “This hybrid emulation platform is a significant advancement for the Qiskit Ecosystem and the quantum industry overall.” Because users may utilise Qiskit Runtime on their own classical resources, the platform simplifies algorithm creation and improvement for quantum developers of all levels. Dell wants to work with Dell to expand the quantum sector.

Quantum technology lets the Qiskit Runtime environment calculate in a day what would have taken weeks. Qiskit uses open-source technology, allowing third-party development and integration to progress the field. The hybrid emulation platform will accelerate algorithm development and use case identification and increase developer ecosystem accessibility.

GitHub has all the tested solution information. Testing revealed these important findings:

Quick Setup Cloud-native Kubernetes powers conventional and quantum processing on the platform. Customer deployment to on-premises infrastructure is easy. Customers used to transmit workloads and data to the cloud for processing.

Faster Results Running and queuing each quantum circuit is no longer essential. Performance and development time are improved by combining conventional and quantum algorithms.

Enhanced Security Classical computing—data processing, optimisation, and algorithm execution—can be done on-premises, improving privacy and security.

Selectivity and Cost Using an on-premise infrastructure solution might save money and provide you an edge over cloud service providers. This model may be run using the Qiskit Aer simulator or other systems, giving quantum solution selection freedom.

The rising workload levels for quantum computing need expansion of classical infrastructure, including servers, desktops, storage, networking, GPUs, and FPGAs. The hybrid emulation platform is what IT directors need to simulate quantum and traditional calculations on their infrastructure.

Running Dell Qiskit

Qiskit Dell Runtime runs classical-quantum programs locally and on-premises. This platform develops and executes hybrid classical-quantum code bundles. The Qiskit Runtime API-powered execution paradigm integrates quantum and conventional execution.

Simulation, emulation, and quantum hardware can be integrated on this platform. Qiskit lets developers abstract source code for simple execution across execution environments.

Windows and Linux are used to test Qiskit-Dell-Runtime.

Introduction to Qiskit

Qiskit Dell Runtime does hybrid classical-quantum calculations locally and remotely. Qiskit experience is recommended before using the platform.

Architecture

The platform offers server-side and client-side provider components.

Client-side provider

DellRuntimeProvider must be installed on client devices. The provider defaults to local execution and may be used immediately. This provider can also connect to server-side platforms, letting users operate servers and accomplish operations from one API.

Server-side components

Simple design gives server-side components a lightweight execution environment. Orchestrator, a long-running microservice, handles DellRuntimeProvider requests.

Starting a job will create a pod to perform classical and vQPU workloads at runtime.

Configuring Database

Code and execution parameters supplied by users will be stored in a database. This platform deploys MySQL by default. Users who want to switch databases should check these installations' database settings.

SSO

SSO integration is disabled by default to simplify sandbox creation. Integration hooks provide easy integration with several SSO systems on the platform.

Multi-Backend Support

The Qiskit Aer simulation engine handles quantum execution by default. Change the quantum backend by providing backend-name in the task input area. Qiskit may support several emulation, simulation, and QPU backends simply altering the code.

Emulation vs. Simulation

Emulation engines utilise deterministic calculations to calculate algorithm outputs, whereas simulation engines use quantum circuits to quantify probabilities.

The Hybrid Emulation Platform simulates and emulates depending on the backend.

The VQE example in the manual or a Qiskit lesson might help you decide when to use simulation or emulation.

Free Courses on IBM Quantum Learning

IBM has launched a series of free course for learning the basics of quantum computing and how to use the IBM Quantum services (here the link).

At the moment I’m writing there are four courses:

Basics of quantum information

First unit in the series, the course explains the basis of quantum computing at a detailed mathematical level, it requires knowing a bit of linear algebra, but also fascinating subjects like: quantum teleportation (no, sadly it’s not like Star Trek) and superdense coding.

Fundamentals of quantum algorithms

This second unit explores the advantages of quantum computers over classical computers

Variational algorithm design

This course teaches how to write variational algorithms and how to use Qiskit, the IBM API for quantum computing.

Practical introduction to quantum-safe cryptography Quantum computers can do what a classical computer can’t: use brute force and be quick, so they can break common cryptography. This course teaches how to use encryption that cannot be break so easily.

Quantum Computing with Qiskit Free Course | 1 Year | Q World

Exciting News: QWorld’s QClass23/24 Your Gateway to Quantum Computing! Are you ready to dive into the fascinating world of quantum computing, algorithms, and programming? Look no further! QWorld is thrilled to announce the launch of our two-semester-long QClass23/24, beginning in September 2023 and running until May 2024. Join us for an immersive virtual experience that will equip you with the…

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Power of Quantum Computing 02

Utilizing the Potential of Quantum Computing.

A revolutionary technology, quantum computing holds the promise of unmatched computational power. Development of quantum software is in greater demand as the field develops. The link between the complicated underlying hardware and the useful applications of quantum computing is provided by quantum software. The complexities of creating quantum software, its potential uses, and the difficulties developers face will all be covered in this article.

BY KARTAVYA AGARWAL

First, a primer on quantum computing.

Contrary to traditional computing, quantum computing is based on different principles. Working with qubits, which can exist in a superposition of states, is a requirement. These qubits are controlled by quantum gates, including the CNOT gate and the Hadamard gate. For the creation of quantum software, comprehension of these fundamentals is essential. Qubits and quantum gates can be used to create quantum algorithms, which are capable of solving complex problems more quickly than conventional algorithms. Second, there are quantum algorithms. The special characteristics of quantum systems are specifically tapped into by quantum algorithms. For instance, Shor's algorithm solves the factorization issue and might be a threat to traditional cryptography. The search process is accelerated by Grover's algorithm, however. A thorough understanding of these algorithms and how to modify them for various use cases is required of quantum software developers. They investigate and develop new quantum algorithms to address issues in a variety of fields, including optimization, machine learning, and chemistry simulations. Quantum simulation and optimization are the third point. Complex physical systems that are difficult to simulate on traditional computers can be done so using quantum software. Scientists can better comprehend molecular structures, chemical processes, and material properties by simulating quantum systems. Potential solutions for logistics planning, financial portfolio management, and supply chain optimization are provided by quantum optimization algorithms. To accurately model these complex systems, quantum software developers work on developing simulation frameworks and algorithm optimization techniques. The 4th Point is Tools and Languages for Quantum Programming. Programming languages and tools that are specific to quantum software development are required. A comprehensive set of tools and libraries for quantum computing are available through the open-source framework Qiskit, created by IBM. Another well-known framework that simplifies the design and simulation of quantum circuits is Cirq, created by Google. Incorporating quantum computing with traditional languages like C, the Microsoft Quantum Development Kit offers a quantum programming language and simulator. These programming languages and tools are utilized by developers to create quantum hardware, run simulations, and write quantum circuits. The 5th point is quantum error correction. Störungs in the environment and flaws in the hardware can lead to errors in quantum systems. Quantum computations are now more reliable thanks to quantum error correction techniques that reduce these errors. To guard against errors and improve the fault tolerance of quantum algorithms, developers of quantum software employ error correction codes like the stabilizer or surface codes. They must comprehend the fundamentals of error correction and incorporate these methods into their software designs. Quantum cryptography and secure communication are the sixth point. Secure communication and cryptography are impacted by quantum computing. Using the concepts of quantum mechanics, quantum key distribution (QKD) offers secure key exchange and makes any interception detectable. Post-quantum cryptography responds to the danger that quantum computers pose to already-in-use cryptographic algorithms. To create secure communication protocols and investigate quantum-resistant cryptographic schemes, cryptographers and quantum software developers work together. Point 7: Quantum machine learning A new field called "quantum machine learning" combines machine learning with quantum computing. The speedup of tasks like clustering, classification, and regression is being studied by quantum software developers. They investigate how quantum machine learning might be advantageous in fields like drug discovery, financial modeling, and optimization. Point 8: Validation and testing of quantum software. For accurate results and trustworthy computations, one needs trustworthy quantum software. Different testing methodologies are used by quantum software developers to verify the functionality and efficiency of their products. To locate bugs, address them, and improve their algorithms, they carry out extensive testing on simulators and quantum hardware. Quantum software is subjected to stringent testing and validation to guarantee that it produces accurate results on various platforms. Point 9: Quantum computing in the study of materials. By simulating and enhancing material properties, quantum software is crucial to the study of materials. To model chemical processes, examine electronic architectures, and forecast material behavior, researchers use quantum algorithms. Variational quantum eigensolvers are one example of a quantum-inspired algorithm that makes efficient use of the vast parameter space to find new materials with desired properties. To create software tools that improve the processes of materials research and discovery, quantum software developers work with materials scientists. Quantum computing in financial modeling is the tenth point. Quantum software is used by the financial sector for a variety of applications, which helps the industry reap the benefits of quantum computing. For portfolio optimization, risk assessment, option pricing, and market forecasting, quantum algorithms are being investigated. Financial institutions can enhance decision-making processes and acquire a competitive advantage by utilizing the computational power of quantum systems. Building quantum models, backtesting algorithms, and converting existing financial models to quantum frameworks are all tasks carried out by quantum software developers.

FAQs:. What benefits can software development using quantum technology offer? Complex problems can now be solved exponentially more quickly than before thanks to quantum software development. It opens up new opportunities in materials science, machine learning, optimization, and cryptography. Is everyone able to access quantum software development? Despite the fact that creating quantum software necessitates specialized knowledge, there are tools, tutorials, and development frameworks available to support developers as they begin their quantum programming journey. What are the principal difficulties faced in creating quantum software? Algorithm optimization for particular hardware, minimization of quantum errors through error correction methods, and overcoming the dearth of established quantum development tools are among the difficulties. Are there any practical uses for quantum software? Yes, there are many potential uses for quantum software, including drug discovery, financial modeling, traffic optimization, and materials science. What can be done to advance the creation of quantum software? Researchers, programmers, contributors to open-source quantum software projects, and people working with manufacturers of quantum hardware to improve software-hardware interactions are all ways that people can make a difference. Conclusion: The enormous potential of quantum computing is unlocked in large part by the development of quantum software. The potential for solving difficult problems and revolutionizing numerous industries is exciting as this field continues to develop. We can use quantum computing to influence the direction of technology by grasping its fundamentals, creating cutting-edge algorithms, and utilizing potent quantum programming languages and tools. link section for the article on Quantum Software Development: - Qiskit - Website - Qiskit is an open-source quantum computing framework developed by IBM. It provides a comprehensive suite of tools, libraries, and resources for quantum software development. - Cirq - Website - Cirq is a quantum programming framework developed by Google. It offers a platform for creating, editing, and simulating quantum circuits. - Microsoft Quantum Development Kit - Website - The Microsoft Quantum Development Kit is a comprehensive toolkit that enables quantum programming using the Q# language. It includes simulators, libraries, and resources for quantum software development. - Quantum Computing for the Determined - Book - "Quantum Computing for the Determined" by Alistair Riddoch and Aleksander Kubica is a practical guide that introduces the fundamentals of quantum computing and provides hands-on examples for quantum software development. - Quantum Algorithm Zoo - Website - The Quantum Algorithm Zoo is a repository of quantum algorithms categorized by application domains. It provides code examples and explanations of various quantum algorithms for developers to explore. Read the full article

WEF schedules Quantum Technology conference as Europe moves more into quantum-666?

COGwriter

The European-based World Economic Forum (WEF) has announced a virtual quantum conference it has set for next week:

Innovation and Quantum Technology27 March, 15:00 CETQuantum technology is transforming industries and solving some of the world’s most complex challenges. From breakthroughs in healthcare and finance to advancements in artificial intelligence and data security, quantum innovation is redefining what’s possible. …

Explore Strategic Intelligence: Quantum EconomyQuantum technologies will impact many critical industries and inspire new business models. Diverse technologies such as quantum computing, quantum communications, quantum sensing, and quantum materials have given rise to new industry players and promising solutions for end users, greater sustainability, and new answers to hitherto unsolved problems. Quantum technology will eventually permeate and affect every key sector of the economy and take us into a period likely to be referred to as the “post-quantum era.”  …

The World Economic Forum, committed to improving the state of the world, is the International Organization for Public-Private Cooperation. The Forum engages the foremost political, business, cultural and other leaders of society to shape global, regional and industry agendas.

Yes, the WEF is correct that Quantum technologies will impact many.

European nations are getting more involved with quantum tech as the following shows:

IBM and Basque Government to Launch Europe’s First Quantum Computing Hub in Spain

March 20, 2025

IBM … and the Basque Government have announced plans to install Europe’s first IBM Quantum System Two in San Sebastián, Spain. This initiative is part of the BasQ project, which seeks to position the Basque Country as a center for quantum technology development.

The IBM Quantum System Two will be housed at the IBM Euskadi Quantum Computational Center on the Ikerbasque Foundation’s main campus in San Sebastián. The system is expected to be operational by the end of 2025.

The system will be powered by a 156-qubit IBM Quantum Heron processor, designed to execute complex algorithms beyond the capabilities of classical computers. It will leverage Qiskit software to run quantum circuits with up to 5,000 two-qubit gate operations, expanding the potential for computational research in various fields. https://www.tipranks.com/news/ibm-and-basque-government-to-launch-europes-first-quantum-computing-hub-in-spain

Spain is not the only place in Europe that these quantum supercomputers are planned for.

Notice the following from last Fall:

New JUPITER module strengthens leading position of Europe’s upcoming Exascale Supercomputer

The journey towards Europe’s first exascale supercomputer, JUPITER, at Forschungszentrum Jülich is progressing at a robust pace. A major milestone has just been reached with the completion of JETI, the second module of this groundbreaking system. By doubling the performance of JUWELS Booster—currently the fastest supercomputer in Germany—JETI now ranks among the world’s most powerful supercomputers, as confirmed today at the Supercomputing Conference SC in Atlanta, USA. The JUPITER Exascale Transition Instrument, JETI, is already one-twelfth of the power of the final JUPITER system, setting a new benchmark on the TOP500 list

18 November 2024

Built by the Franco-German team ParTec-Eviden, Europe’s first exascale supercomputer, JUPITER, will enable breakthroughs in the use of artificial intelligence (AI) and take scientific simulations and discoveries to a new level. Procured by the European supercomputing initiative EuroHPC Joint Undertaking (EuroHPC JU), it will be operated by the Jülich Supercomputing Centre (JSC), one of three national supercomputing centres within the Gauss Centre for Supercomputing (GCS). Since the middle of this year, JUPITER has been gradually installed at Forschungszentrum Jülich. Currently, the modular high-performance computing facility, known as the Modular Data Centre (MDC), is being delivered to house the supercomputer. The hardware for JUPITER’s booster module will occupy 125 racks, which are currently being pre-installed at Eviden’s flagship factory in Angers, France, and will then be shipped to Jülich ready for operation.

The final JUPITER system will be equipped with approximately 24,000 NVIDIA GH200 Grace Hopper Superchips, specifically optimized for computationally intensive simulations and the training of AI models. This will enable JUPITER to achieve more than 70 ExaFLOP/s in lower-precision 8-bit calculations, making it one of the world’s fastest systems for AI. The current JETI pilot system contains 10 racks, which is exactly 8 percent of the size of the full system. In a trial run using the Linpack Benchmark for the TOP500 list, JETI achieved a performance of 83 petaflops, which is equivalent to 83 million billion operations per second (1,000 PetaFLOP is equal to 1 ExaFLOP). With this performance JETI ranks 18th on the current TOP500 list of the world’s fastest supercomputers, doubling the performance of the current German flagship supercomputer JUWELS Booster, also operated by JSC. …

In order to equip Europe with a world-leading supercomputing infrastructure, the EuroHPC JU has already procured nine supercomputers, located across Europe. No matter where in Europe they are located, European scientists and users from the public sector and industry can benefit from these EuroHPC supercomputers via the EuroHPC Access Calls to advance science and support the development of a wide range of applications with industrial, scientific and societal relevance for Europe.https://www.mynewsdesk.com/partec/pressreleases/new-jupiter-module-strengthens-leading-position-of-europes-upcoming-exascale-supercomputer-3355162?utm_source=rss&utm_medium=rss&utm_campaign=Alert&utm_content=pressrelease

The JUPITER Exascale Transition Instrument, JETI, is already one-twelfth of the power of the final JUPITER system, setting a new benchmark on the TOP500 list. 11/19/24 https://www.hpcwire.com/off-the-wire/new-jupiter-module-strengthens-leading-position-of-europes-upcoming-exascale-supercomputer/?utm_source=twitter&utm_medium=social&utm_term=hpcwire&utm_content=05dac910-6268-4a88-b01b-1f0dd233eca9

Exascale: the Engine of Discovery

Exascale computing will have a profound impact on everyday life in the coming decades. At 1,000,000,000,000,000,000 operations per second, exascale supercomputers will be able to quickly analyze massive volumes of data and more realistically simulate the complex processes and relationships behind many of the fundamental forces of the universe.

accessed 12/19/24 https://www.exascaleproject.org/what-is-exascale/

The “much more” would seem to include military applications as well as the surveillance and control of people and buying and selling.

This sounds like another step to 666.

The speed of process is so fast that it is mindboggling.

The British Broadcasting Corporation (BBC) warned about these type of computers years ago:

What is the quantum apocalypse and should we be scared?

27 January 2022

Imagine a world where encrypted, secret files are suddenly cracked open – something known as “the quantum apocalypse”.

Put very simply, quantum computers work completely differently from the computers developed over the past century. In theory, they could eventually become many, many times faster than today’s machines.

That means that faced with an incredibly complex and time-consuming problem – like trying to decrypt data – where there are multiple permutations running into the billions, a normal computer would take many years to break those encryptions, if ever.

But a future quantum computer, in theory, could do this in just seconds. …

Data thieves

A number of countries … are working hard and investing huge sums of money to develop these super-fast quantum computers with a view to gaining strategic advantage in the cyber-sphere.

Every day vast quantities of encrypted data – including yours and mine – are being harvested without our permission and stored in data banks, ready for the day when the data thieves’ quantum computers are powerful enough to decrypt it. …

Everything we do over the internet today,” says Harri Owen, chief strategy officer at the company PostQuantum, “from buying things online, banking transactions, social media interactions, everything we do is encrypted.

“But once a functioning quantum computer appears that will be able to break that encryption… it can almost instantly create the ability for whoever’s developed it to clear bank accounts, to completely shut down government defence systems – Bitcoin wallets will be drained.” https://www.bbc.com/news/technology-60144498

Monitoring the buying and selling of everything is something that quatum or other computers can do.

The Bible shows that a European power will arise that will control buying and selling:

16 He causes all, both small and great, rich and poor, free and slave, to receive a mark on their right hand or on their foreheads, 17 and that no one may buy or sell except one who has the mark or the name of the beast, or the number of his name. Here is wisdom. Let him who has understanding calculate the number of the beast, for it is the number of a man: His number is 666. (Revelation 13:16-17)

When the Apostle John penned the above, such control of buying and selling was not possible.

However, with supercomputers. AI, and digital payments, it is now.

The European Union has already announced it was launching surveillance software (see ‘The EU is allowing the linking of face recognition databases to create a mega surveillance system’ 666 infrastructure being put into place).

And, now, it looks to be closer to having the supercomputer hardware to make it more of a reality.

There is also an office in the EU to enforce its financial rules.

When it was announced, we put together the following video:

9:55

EU Setting Up 666 Enforcer?

The European Union is in the process of establishing the European Public Prosecutor’s Office. This is a major, first-of-its-kind move, with the EU setting up a European-wide prosecutor’s office that will have power to investigate and charge people for financial crimes committed against the EU. It looks like this type of office may end up persecuting those that do not have the mark of the Beast when they “buy or sell” as that will later be considered a financial crime in Europe. What does 666 mean? How has that name be calculated? How can we be certain that this is a prophecy for Europe and not Islam? Is the appointment of this new office of significant prophetic importance? Dr. Thiel addresses these issues and more by pointing to scriptures, news items, and historical accounts.

Here is a link to the sermonette video: EU Setting Up 666 Enforcer?

The European Public Prosecutor’s Office officially started operations on 1 June 2021 (https://www.eppo.europa.eu/en/background).

So, yes, there is an enforcer.

Now there is hardware, more surveillance software, and massively faster computation ability.

Persecution will come.

Jesus warned Christians to flee persecution:

23 When they persecute you in this city, flee to another. For assuredly, I say to you, you will not have gone through the cities of Israel before the Son of Man comes (Matthew 10:23).

Surveillance software on supercomputers may well be a factor in fleeing from multiple cities.

Europe in particular is moving more and more towards becoming an Orwellian totalitarian state (watch also Is Germany Becoming Orwell’s 1984?).

When will this fully be in place?

After the Gospel of the Kingdom of God has sufficiently reached the world the end comes and the Beast will rise up (Matthew 24:14-22, Revelation 13, 17:12-13).

We are getting closer to that day.

It looks like quantum supercomputers are another step towards 666.

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Quantum Computing & Python: What Developers Need to Know

Quantum computing is one of the most exciting frontiers in technology, promising to revolutionize industries by solving problems that are currently impossible for classical computers. Python, being a versatile and widely used programming language, has become the go-to tool for quantum computing simulations and research. In this blog, we’ll explore the fundamentals of quantum computing, how Python fits into the ecosystem, and what developers should know to get started.

Understanding Quantum Computing Basics

Unlike classical computers that use bits (0s and 1s), quantum computers use qubits, which leverage the principles of superposition and entanglement to process information in fundamentally different ways. This allows quantum computers to perform calculations exponentially faster for specific tasks like cryptography, optimization, and complex simulations.

Superposition – A qubit can exist in multiple states (0 and 1) simultaneously, enabling parallel computations.

Entanglement – Qubits can be interconnected, meaning the state of one qubit can instantly influence another, even over vast distances.

Quantum Gates – Instead of traditional logic gates, quantum computing relies on quantum gates that manipulate qubits in unique ways.

Python’s Role in Quantum Computing

Python plays a crucial role in quantum computing, providing user-friendly libraries and frameworks for quantum programming. Here are some of the most popular quantum computing libraries in Python:

Qiskit (by IBM) – A powerful open-source framework for working with quantum computers and simulators.

Cirq (by Google) – Focuses on building, simulating, and running quantum circuits.

PennyLane (by Xanadu) – An advanced library for quantum machine learning.

QuTiP – Designed for quantum physics simulations.

Getting Started with Quantum Computing in Python

If you’re a Python developer looking to explore quantum computing, follow these steps:

Install Qiskit – pip install qiskit

Create a Simple Quantum Circuit

from qiskit import QuantumCircuit circuit = QuantumCircuit(2) circuit.h(0) # Apply Hadamard gate circuit.cx(0, 1) # Apply CNOT gate print(circuit)

Run on a Simulator or Real Quantum Computer – IBM provides free cloud access to quantum computers via IBM Quantum Experience.

Future of Quantum Computing

Quantum computing is still in its early stages, but its potential impact is vast. Fields like cryptography, AI, drug discovery, and climate modeling stand to benefit immensely. As quantum hardware advances, Python developers equipped with quantum programming skills will be in high demand.

Conclusion

Quantum computing is no longer just theoretical—it’s becoming an essential technology for the future. Python developers interested in innovation should start exploring quantum programming today. With tools like Qiskit and Cirq, diving into quantum computing has never been easier. Stay ahead of the curve and be part of the quantum revolution!

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Quantum Literacy in Education: Preparing Students for a Quantum-Powered World

Quantum technology is no longer a distant dream—it’s a reality that’s transforming industries like healthcare, finance, and cybersecurity. As the world moves toward a quantum-powered future, the need for quantum literacy is growing rapidly. To prepare the next generation for this new era, schools and universities are integrating quantum concepts into their curricula, equipping students with the skills they need to thrive in a quantum-driven world. Here’s how education is adapting to this technological shift.

How Quantum Concepts Are Being Integrated into Education

Educational institutions are taking proactive steps to introduce students to quantum computing and its applications. Here’s a look at how they’re making it happen:

1. Adding Quantum Computing to STEM Curricula

Universities such as MIT, Stanford, and Caltech have introduced quantum computing courses as part of their physics, computer science, and engineering programs.

High schools are also beginning to incorporate quantum concepts into their STEM education, often through collaborations with tech companies and research organizations.

2. Hands-On Learning with Quantum Tools

Platforms like IBM Quantum Experience and Qiskit are being used in classrooms to give students hands-on experience with quantum programming and algorithms.

Quantum simulators and cloud-based quantum computers are becoming essential tools, allowing students to experiment with real-world quantum applications.

Key Initiatives Driving Quantum Education

Several programs and partnerships are making quantum literacy more accessible to students at all levels:

1. The Qubit by Qubit Program

This global initiative, led by The Coding School, offers free quantum computing courses to high school and university students. The program has reached over 10,000 students worldwide, providing foundational knowledge and practical experience.

2. Collaborations Between Tech Companies and Schools

Companies like IBM, Google, and Microsoft are partnering with educational institutions to develop quantum curricula and provide access to quantum computing resources.

For example, IBM’s Quantum Educator Program trains teachers to deliver quantum computing lessons, ensuring students receive high-quality instruction.

3. Government Support for Quantum Education

Programs like the U.S. National Quantum Initiative and the EU’s Quantum Flagship include funding for educational initiatives aimed at building a quantum-ready workforce.

Success Stories: Students Thriving Through Quantum Literacy

Quantum literacy programs are already making a significant impact, opening doors to new opportunities and career paths. Here are a few inspiring examples:

1. High School Students Solving Real-World Problems

A group of high school students in the U.S. participated in the Qubit by Qubit program and developed a quantum algorithm to optimize traffic flow in their city. Their project won a national science competition and earned them scholarships to top universities.

2. University Students Leading Quantum Research

At the University of Waterloo, undergraduate students used IBM’s quantum computers to simulate molecular interactions, contributing to groundbreaking research in drug discovery. Their work was published in a leading scientific journal.

3. Encouraging Diversity in Quantum Computing

Programs like IBM’s Quantum Women’s Summit are inspiring more young women to pursue careers in quantum computing. One participant, a college sophomore, interned at a quantum startup and is now pursuing a PhD in quantum physics.

Call-to-Action: Advocate for More Quantum Education Funding

While progress is being made, there’s still much to be done to ensure quantum literacy becomes a standard part of education. Here’s how you can contribute:

Support Educational Programs: Advocate for increased funding for quantum education initiatives at local, national, and international levels.

Foster Partnerships: Encourage collaborations between schools, universities, and tech companies to expand access to quantum resources.

Raise Awareness: Educate others about the importance of quantum literacy and its potential to transform industries and create new opportunities.

Conclusion: INA Solutions’ Role in Shaping the Quantum Future

At INA Solutions, we are committed to empowering businesses and communities with emerging technologies like quantum computing. Our mission is to optimize processes, uncover insights, and drive growth through innovative solutions, expert knowledge, and exceptional service. While we are not an educational institution, we recognize the critical role that education plays in preparing the next generation for a quantum-powered world.

We support initiatives that promote quantum literacy and innovation, whether through strategic consulting, training programs, or partnerships with educational organizations. By working together, we can ensure that quantum literacy becomes a cornerstone of education and a driver of future success.

AI and Quantum Computing: Certifications Shaping the Future of Tech

The convergence of artificial intelligence (AI) and quantum computing represents a groundbreaking shift in technology. Together, these fields promise to solve problems once considered insurmountable, from advanced drug discovery to optimizing global supply chains. As this fusion reshapes industries, professionals equipped with the right knowledge and certifications will lead the way in innovation.

In this article, we explore how AI and quantum computing are transforming the tech landscape, the certifications helping professionals excel in this space, and why investing in education is vital to staying ahead of the curve.

The Synergy of AI and Quantum Computing

AI excels in pattern recognition and decision-making by processing large amounts of data. Quantum computing, on the other hand, leverages quantum mechanics principles to perform complex calculations at unprecedented speeds.

When combined, AI and quantum computing offer immense potential:

Accelerated Machine Learning: Quantum algorithms can speed up AI training processes, leading to faster insights.

Enhanced Problem Solving: From financial modeling to climate simulations, the combined power of AI and quantum computing solves problems traditional computing cannot handle.

Optimized Resource Allocation: Industries like logistics and energy benefit from quantum-optimized AI models, improving efficiency.

This synergy underscores the importance of acquiring skills in both AI and quantum computing — a demand that specialized certifications aim to fulfill.

Top Certifications in AI and Quantum Computing

1. AI+ Quantum™ by AI Certs

AI+ Quantum™ is an advanced course that bridges the gap between AI and quantum computing, making it an ideal choice for professionals aiming to lead in this transformative era.

Key Features:

Covers quantum computing fundamentals and their applications in AI.

Explores quantum machine learning algorithms and their potential use cases.

Hands-on workshops and case studies for real-world application.

Why Choose AI+ Quantum™:

This certification empowers professionals with the skills to understand and implement quantum-enhanced AI solutions, making them indispensable in future tech landscapes.

Use the coupon code NEWCOURSE25 to get 25% OFF on AI CERTS’ certifications. Don’t miss out on this limited-time offer! Visit this link to explore the courses and enroll today.

2. Quantum Computing for Artificial Intelligence by edX

This course, offered by prominent institutions, provides an excellent foundation in quantum computing with a focus on its integration with AI.

Key Features:

An introduction to quantum mechanics and quantum computing basics.

Applications of quantum algorithms in AI and data analysis.

Practical insights into using quantum platforms like IBM Q.

Why Choose This Certification:

The course caters to professionals looking for a solid understanding of quantum computing and its real-world implications in AI.

3. Quantum Machine Learning by Coursera (offered by the University of Toronto)

This program dives into the intersection of machine learning and quantum computing, making it ideal for those aiming to specialize in quantum AI.

Key Features:

Comprehensive modules on quantum-enhanced learning techniques.

Exposure to quantum programming languages like Qiskit.

Collaboration with experts in the field for practical projects.

Why Choose This Certification:

This course offers an in-depth look at how quantum computing enhances machine learning processes, preparing professionals for cutting-edge research and development roles.

Why AI and Quantum Computing Certifications Matter

Competitive Advantage:

With industries rapidly adopting quantum-enhanced AI, certified professionals are in high demand. Certifications validate your expertise, setting you apart in a competitive job market.

Future-Proof Skills:

AI and quantum computing are at the forefront of tech innovation. Learning these skills ensures you remain relevant as these technologies evolve.

Interdisciplinary Expertise:

Understanding the intersection of AI and quantum computing positions you as a leader capable of tackling multifaceted challenges.

Career Growth:

Certifications in AI and quantum computing open doors to roles like Quantum AI Specialist, Quantum Data Scientist, and AI Research Scientist.

Industries Driving AI and Quantum Computing

Several industries are already leveraging the power of AI and quantum computing, highlighting the need for skilled professionals:

Healthcare: Revolutionizing drug discovery and genomic analysis.

Finance: Enhancing risk modeling and fraud detection with quantum algorithms.

Energy: Optimizing renewable energy grids and reducing costs.

Logistics: Solving complex routing and scheduling problems.

Professionals in these sectors benefit immensely from certifications that provide hands-on experience and domain-specific knowledge.

How to Choose the Right Certification

When selecting an AI and quantum computing certification, consider the following factors:

Career Goals:

Identify whether you aim to specialize in research, development, or strategic implementation.

Program Content:

Look for certifications that balance theoretical knowledge with practical applications.

Reputation:

Opt for programs from credible organizations or academic institutions.

Flexibility:

Choose courses that accommodate your schedule, especially if you are working full-time.

Industry Recognition:

Certifications like AI+ Quantum™ by AI Certs are widely recognized and valued by employers.

The Road Ahead for AI and Quantum Computing

As quantum computing becomes more accessible, its integration with AI will unlock unprecedented possibilities. Some emerging trends include:

Quantum Neural Networks: Pushing the boundaries of AI capabilities.

AI-Driven Quantum Simulations: Revolutionizing industries like material science and climate modeling.

Democratization of Quantum AI Tools: Making these technologies accessible to businesses of all sizes.

Professionals who invest in certifications now will be at the forefront of these advancements, driving innovation in their respective fields.

Conclusion

AI and quantum computing are not just technological advancements; they are paradigm shifts that redefine what is possible. For tech professionals, understanding these technologies is essential for driving innovation and solving complex challenges.

Certifications like AI+ Quantum™ by AI Certs, Quantum Computing for Artificial Intelligence by edX, and Quantum Machine Learning on Coursera equip professionals with the skills to lead in this transformative era.

By gaining expertise in these fields, you position yourself as a pioneer, ready to shape the future of technology. Don’t just witness the revolution — be part of it.

Invest in an AI and quantum computing certification today, and take the first step toward a career that defines the future.

IT Sectors jobs in Jobseekerspage.com

JobseekersPage.com offers IT sector job listings across various roles, including software development, cybersecurity, and data analytics. The platform supports advanced search filters for location, experience level, and job type, simplifying the job search process for candidates. Visit JobseekersPage.com to explore current opportunities and apply.

IT (Information Technology) sectors offer a diverse range of jobs, covering everything from software development to cybersecurity. Below is a breakdown of key areas within the IT sector and the types of jobs commonly found in each:

1. Software Development

Roles:

Front-end Developer

Back-end Developer

Full-stack Developer

Mobile App Developer

Game Developer

Skills Required:

Programming languages (e.g., Java, Python, JavaScript, C++)

Frameworks (e.g., React, Angular, Spring)

Version control (e.g., Git)

2. Data Science and Analytics

Roles:

Data Scientist

Data Analyst

Machine Learning Engineer

Business Intelligence Analyst

Skills Required:

Data analysis tools (e.g., Excel, Tableau, Power BI)

Programming languages (e.g., Python, R)

Machine learning frameworks (e.g., TensorFlow, Scikit-learn)

SQL and data visualization

3. Cybersecurity

Roles:

Cybersecurity Analyst

Ethical Hacker/Penetration Tester

Security Architect

Incident Response Analyst

Skills Required:

Network security

Ethical hacking tools (e.g., Metasploit, Wireshark)

Certifications (e.g., CISSP, CEH, CompTIA Security+)

4. Cloud Computing

Roles:

Cloud Engineer

Cloud Architect

DevOps Engineer

Site Reliability Engineer (SRE)

Skills Required:

Cloud platforms (e.g., AWS, Azure, Google Cloud)

Containerization tools (e.g., Docker, Kubernetes)

Automation and CI/CD pipelines

5. Networking

Roles:

Network Engineer

Network Administrator

Wireless Communication Specialist

Skills Required:

Networking protocols (e.g., TCP/IP, DNS)

Hardware configuration

Certifications (e.g., CCNA, CCNP)

6. Artificial Intelligence and Robotics

Roles:

AI Engineer

Robotics Engineer

Natural Language Processing (NLP) Specialist

Skills Required:

AI tools (e.g., OpenAI, IBM Watson)

Robotics programming (e.g., ROS, MATLAB)

Deep learning techniques

7. IT Management and Support

Roles:

IT Project Manager

IT Support Specialist

System Administrator

Database Administrator

Skills Required:

Project management methodologies (e.g., Agile, Scrum)

ITIL and service management

Database tools (e.g., Oracle, MySQL)

8. Web Development

Roles:

Web Developer

Web Designer

SEO Specialist

Skills Required:

HTML, CSS, JavaScript

Content management systems (e.g., WordPress)

SEO and web analytics

9. Emerging Technologies

Roles:

Blockchain Developer

IoT Engineer

Quantum Computing Researcher

Skills Required:

Blockchain frameworks (e.g., Ethereum, Hyperledger)

IoT platforms and sensors

Quantum programming (e.g., Qiskit)

10. Product and UX Design

Roles:

UX/UI Designer

Product Manager

Interaction Designer

Skills Required:

Design tools (e.g., Figma, Adobe XD)

User research and prototyping

Agile product development

11. IT Consulting

Roles:

IT Consultant

Systems Analyst

Technology Strategist

Skills Required:

Business acumen

Systems integration

Technical writing and documentation

18 a 23 de novembro

documentação nos projetos

github pra codespace

vem com o vscode instalado e o jupyter , tem que criar uma conta

tem os codicos do jupyter pra download por capitulo do livro no link

https://github.com/PacktPublishing/A-Practical-Guide-to-Quantum-Machine-Learning-and-Quantum-Optimization

https://github.com/PacktPublishing/The-Complete-Quantum-Computing-Course-for-Beginners-

https://github.com/PacktPublishing/Learn-Quantum-Computing-with-Python-and-IBM-Quantum-Experience

https://github.com/PacktPublishing/Quantum-Computing-in-Practice-with-Qiskit-and-IBM-Quantum-Experience

https://github.com/PacktPublishing/Quantum-Computing-Algorithms

QASM

OpenQASM

quantum assembly

https://www.quantumblockchains.io/

https://www.quantumblockchains.io/wp-content/uploads/2023/06/QBCK_WhitePaper.pdf

https://matplotlib.org/stable/gallery/index.html

RIKEN And Cleveland Clinic Use Qiskit For Quantum Innovation

IBM Introduces Its Most Cutting-Edge Quantum Computers, Advancing Quantum Advantage and New Scientific Value. The most effective quantum software in the world, Qiskit, can accurately expand the length and complexity of specific circuits to 5,000 two-qubit operations on IBM quantum computers. Rensselaer Polytechnic Institute advances quantum-centric supercomputing, while RIKEN and Cleveland Clinic use Qiskit to combine quantum and classical resources to investigate novel, scientifically important challenges.

IBM, Algorithmiq, Qedma, QunaSys, Q-CTRL, and Multiverse Computing’s Qiskit services may boost performance while making it easier to create next-generation algorithms.

IBM today revealed quantum hardware and software advances to run complicated algorithms on IBM quantum computers with unprecedented speed, accuracy, and scalability at its first-ever IBM Quantum Developer Conference.

Qiskit may now be used to precisely execute certain classes of quantum circuits with up to 5,000 two-qubit gate operations on IBM Quantum Heron, the company’s most powerful quantum processor to date and available in IBM’s worldwide quantum data centers. These features now allow users to further investigate how quantum computers might address scientific issues in a variety of fields, including high-energy physics, chemistry, materials science, and life sciences.

As IBM and its partners get closer to quantum advantage and IBM’s cutting-edge, error-corrected system, which is scheduled for 2029, this further advances the era of quantum utility and continues to meet milestones on IBM’s Quantum Development Roadmap.

Certain mirrored kicked Ising quantum circuits with up to 5,000 gates may be executed with the combined enhancements of IBM Heron and Qiskit. This is about twice as many gates as IBM’s 2023 demonstration of quantum usefulness. Through this effort, IBM’s quantum computers’ performance is significantly enhanced beyond what can be achieved using brute-force conventional simulation techniques.

The utility experiment from 2023, which was published in Nature, showed the speed findings in terms of processing time per data point, which came to 112 hours. Using the same data points, the same experiment was conducted on the newest IBM Heron CPU, which is 50 times quicker and can be finished in 2.2 hours.

To make it easier for developers to create intricate quantum circuits with speed, precision, and stability, IBM has further developed Qiskit into the most powerful quantum software in the world. This is supported by data collected and posted on arXiv.org using Benchpress, an open-source benchmarking tool that IBM used to evaluate Qiskit on 1,000 tests, most of which were from third parties. The results showed that Qiskit was the most dependable and high-performing quantum software development kit when compared to other platforms.

New Software Tools to Advance Development of Next-Generation Algorithms

With additional Qiskit services like generative AI-based capabilities and software from IBM partners, the IBM Quantum Platform is further broadening possibilities and enabling a growing network of specialists from many sectors to develop next-generation algorithms for scientific research.

This includes tools like the Qiskit Transpiler Service, which powers the effective optimization of quantum circuits for quantum hardware with AI; Qiskit Code Assistant, which assists developers in creating quantum code using generative AI models based on IBM Granite; Qiskit Serverless, which runs initial quantum-centric supercomputing approaches across quantum and classical systems; and the IBM Qiskit Functions Catalog, which makes services from IBM, Algorithmiq, Qedma, QunaSys, Q-CTRL, and Multiverse Computing available for features like managing quantum noise performance and simplifying the development of quantum algorithms by abstracting away the complexities of quantum circuits.

By utilizing steps towards quantum-centric supercomputing approaches, Algorithmiq’s tensor error network mitigation algorithm (TEM), accessible through the IBM Qiskit Functions Catalog, provides the fastest quantum runtime it’ve yet to provide to users while providing state-of-the-art error mitigation for circuits at utility scale.

“This are expanding TEM’s capabilities to support circuits with up to 5,000 entangled quantum gates, a milestone for scaling quantum experiments and solving complicated issues, given the recent breakthroughs it’ve achieved to integrate quantum computers with post-processing on GPUs. This may pave the way for quantum calculations and simulations that were previously limited by noise constraints.

The goal of Qedma is to provide services that enable the customers to operate the longest and most complicated quantum circuits, and advancements in IBM quantum hardware and software are essential to this goal. Together with to own successes in error mitigation, which can provide through Qedma’s service in the IBM Qiskit Functions Catalog, its are eager to continue it goal of empowering users worldwide to develop algorithms using today’s quantum systems and produce results that are more and more accurate and valuable to science.

Qiskit Fuels Quantum and Classical Integration Towards Future of Computing

IBM’s vision of quantum-centric supercomputing, the next step in high-performance computing, aims to combine sophisticated quantum and classical computers running parallelized workloads to easily deconstruct complex problems using powerful software. This will allow each architecture to solve specific portions of an algorithm for which it is most appropriate. Such software is being developed to rapidly and easily piece issues back together, enabling the execution of algorithms that are difficult or impossible for each computer paradigm to do alone.

The Cleveland Clinic, a renowned academic medical center and biomedical research institution with an on-site and utility-scale IBM Quantum System One, and RIKEN, a national scientific research institute in Japan, are investigating algorithms for electronic structure problems that are essential to chemistry.

In order to properly mimic complicated chemical and biological systems a job that has long been thought to need fault-tolerant quantum computers these endeavors mark the beginning of quantum-centric supercomputing technologies.

Methods based on the parallel classical processing of individual quantum computer samples are early examples of these kinds of operations. Researchers from IBM and RIKEN have carried out sample-based quantum diagonalizations in quantum-centric supercomputing environments, building on earlier methods like QunaSys’s QSCI method. These methods use quantum hardware to precisely model the electronic structure of iron sulfides, a compound that is widely found in organic systems and nature.

The Cleveland Clinic is using this same technique, which is now available as a deployable Qiskit service, to investigate how it might be applied to implement quantum-centric simulations of noncovalent interactions molecule-to-molecule bonds that are crucial to many processes in chemical, biological, and pharmaceutical science.

This study exemplifies the success of to research collaboration, which combines the world-renowned healthcare and life sciences expertise of Cleveland Clinic with IBM’s cutting-edge technology. Using state-of-the-art tools like Qiskit, it are working together to push beyond established scientific limits in order to further study and discover novel therapies for patients worldwide.

Intermolecular interactions are crucial for possible future applications in drug discovery and design, and it were able to study them for the first time on the on-site IBM Quantum System One at Cleveland Clinic by utilizing the partners at IBM’s sophisticated electronic structure algorithm for quantum computing.

RIKEN Center for Computational Science

Through the Japan High Performance Computing-Quantum (JHPC-Quantum) project, which is being carried out by the RIKEN Center for Computational Science (R-CCS), it supercomputer, Fugaku, will be integrated with an on-premises IBM Quantum System Two that is powered by an IBM Quantum Heron processor in order to create a quantum-HPC hybrid computing platform. The director of the Quantum-HPC Hybrid Platform Division at the RIKEN Center for Computational Science stated. “It will strongly support the initiative’s goal of demonstrating quantum-centric supercomputing approaches by using it platform as a first step towards this new computing architecture in the era of quantum utility.”

Read more on govindhtech.com

IBM makes developing for quantum computers easier with the Qiskit Functions Catalog

IBM today launched the Qiskit Functions Catalog, a new set of services that aims to make programming quantum computers easier by abstracting away many of the complexities of working with these machines. “I do think it’s the next big transition ince we put the quantum computer on the cloud,” Jay Gambetta, IBM’s VP in charge […] © 2024 TechCrunch. All rights reserved. For personal use only. Source:…

IBM releases a new version of Qiskit SDK to address the challenge of optimizing the performance and functionality of the existing version. Qiskit SDK is a leading quantum computing software development kit. As quantum computing evolves, the need for #AI #ML #Automation

Bell's Inequality: The weirdest theorem in the world | Nobel Prize 2022 Last year, in 2022, John Clauser, Alain Aspect, and Anton Zeilinger were awarded the Nobel Prize in physics. Their groundbreaking work was built upon one of the most significant discoveries in the history of physics: Bell's Theorem, which was originally formulated by the late John Stewart Bell. In this video, we delve into the reasons why Bell's Theorem stands as one of the most important and perplexing results in the annals of physics. Join us as we celebrate the achievements of these three remarkable scientists who, through their contributions, laid the foundation for cutting-edge technologies rooted in quantum information. https://ift.tt/QkbmtPJ #qiskit #ibm #nobelprize via YouTube https://www.youtube.com/watch?v=9OM0jSTeeBg

When quantum software errs - Technology Org

New Post has been published on https://thedigitalinsider.com/when-quantum-software-errs-technology-org/

When quantum software errs - Technology Org

Quantum programs, too, can be mistaken. Researchers from the Software Lab at the Department of Computer Science at the University of Stuttgart are investigating methods of how the results delivered by these programs can be reliably verified. As part of the new “QPTest” project by the German Research Foundation (DFG), they want to develop a comprehensive testing framework for quantum computing platforms.

Simultaneously 1 and 0: quantum bits act differently from classical bits and need new test routines.

Where conventional computers reach their limits, quantum computers will be able to solve complex problems many times faster in the future. However, it is not yet possible to reliably verify the consistency of quantum computing platform results. The project “QPTest: Automated Testing of Quantum Computing Platforms“ of the Software Lab at the Department of Computer Science at the University of Stuttgart is intended to change this. The researchers want to systematically identify bugs in quantum computing software platforms and thereby ensure reliable computation.

Using quantum computers efficiently

“Quantum computers revolutionize computation and, simultaneously, present us with new software challenges,” says Prof. Dr. Michael Pradel, Head of the Software Lab and Managing Director of the Institute of Software Engineering (ISTE) at the University of Stuttgart. “The quality of software platforms will be crucial for using quantum computers effectively,” explains the expert in failure analysis of traditional computer infrastructures and quantum computing platforms. To be able to ensure this quality, the scientists need a programming framework in which novel, automated testing procedures can be used. As part of “QPTest”, Pradel and his team want to develop and try out such a framework.

No two program runs are the same

Unlike classical bits, quantum mechanical bits, in short qubits, are able to occupy the states 1 and 0 simultaneously. Qubits are the basis for computations on powerful quantum computers, which are intended to be used in simulation science, cryptography, and AI applications, among other things. However, no two program runs are the same. There are no unique and reproducible results. Instead, the systems deliver a probability distribution over states that were measured on qubits. If the probability distribution deviates from expected values, this may suggest a critical error within the platform used or just indicate that noise from the underlying hardware is interfering with the computations. Consequently, the researchers cannot rely on conventional, standardized test routines and are developing their own framework for the novel computing paradigm.

QPTest in combination with open-source platforms

At the end of “QPTest”, the scientists want to be able to identify real bugs in quantum computing platforms reliably and with a small number of program runs. In addition, statistical correction methods are to reduce the number of false alarms. The researchers aim to evaluate the findings they make in the course of the project on common open-source platforms such as Qiskit (IBM Research) and Cirq (Google). These platforms provide computer scientists with tools and resources to develop quantum algorithms and write quantum programs. “If our project is successful, we will then be able to lay the foundation for the automated examination of quantum platforms for errors,” Prof. Pradel points out.

Source: University of Stuttgart

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