#amazonbraket

Overview

Kvantify Qrunch, an Amazon Braket-compatible software, enables complicated quantum chemical simulations. The platform lets researchers execute complex molecular calculations on noisy quantum hardware using hybrid algorithms like FAST-VQE and BEAST-VQE. The application simplifies computational chemistry by automating circuit building and providing access to cloud-based quantum computers. A drug development case study shows the system's potential to scale to 80 qubits, bridging theoretical quantum mechanics and industrial application. It concludes that projective embedding and unique gate selection techniques enable high-accuracy modeling of large-scale chemical interactions.

Kvantify Qrunch on Amazon Braket

New software integration brings quantum computing to computational chemists' workstations, changing biotech and pharmaceutical industries. Kvantify and Amazon Web Services launched Qrunch on Amazon Braket, a software package for complex quantum chemical computations on Noisy Intermediate-Scale Quantum (NISQ) devices.

Chemistry remains a viable quantum advantage sector because molecular interactions are inherently quantum mechanical. Physical noise in quantum hardware and the large learning curve needed for chemists to develop and route sophisticated quantum circuits have long been the field's principal obstacles. Kvantify Qrunch addresses these challenges by providing a “missing software link” that abstracts quantum physics into Python.

Simplifying Quantum Workflow

Chemistry professionals have often felt like they were learning a new language when switching to quantum technology. Qrunch removes these barriers by letting academics build apps without hardware backends or circuit design. The program guides users through molecular configurations, whether supplied as PDB or standard.xyz files, and ensures all simulation criteria are met using a fluent building style.

One of the platform's highlights is projective embedding. This “onion-like” structure lets researchers employ computer resources judiciously. Chemists can employ advanced quantum computing for the “inner regions” of a molecule, where complex electronic correlations are most significant, and molecular mechanics or DFT for the outer layers. By using quantum power precisely when conventional ways fail, this hybrid methodology can simulate far larger systems than before.

Exclusive BEAST and FAST Algorithms

Qrunch uses Kvantify's unique FAST-VQE and BEAST-VQE algorithms. These “Variational Quantum Eigensolver” methods are designed for ground-state energy calculations. BEAST-VQE (Binary-Excitation Adaptive Selection Tool) is more accurate and scalable than typical VQE methods, which can be overwhelmed by noise and resource demands.

BEAST-VQE reduces circuit complexity, simplifies Hamiltonian measurements to a constant value, and decreases qubit requirements by treating paired electron excitations as bosonic particles. This is a big improvement over “vanilla” VQE techniques, where measurement needs increase exponentially with system scale. Due to their noise-resilience, both algorithms can extract high-quality data even with today's defective equipment.

Real-World Impact: Osteoporosis Showcase

Kvantify and AWS demonstrated the platform's scalability with a postmenopausal osteoporosis case study. Simulations focused on Cathepsin-K and its link to the potent covalent inhibitor odanacatib.

Covalent ligands, or drugs that make a permanent chemical bond with their target, are difficult to simulate using force fields because they can't capture the shifting electron distributions during bond formation. By establishing a quantum active space around the enzyme's sulfur atom and the ligand's carbon group and using DFT to incorporate the rest of the environment, the researchers accurately described this complex binding process.

Amazon Braket and Rigetti Ankaa-3 hardware scaled the calculation to 80 qubits. Traditional methods on classical computers cannot simulate 80 orbitals and 24 electrons without considerable assumptions. The results showed that Qrunch can employ large-scale hardware with current noise levels, matching noiseless benchmarks.

Getting to 100 Qubits and Beyond

By overcoming the bottleneck where classical computing workloads increase dramatically as state vectors climb, Kvantify's memory-restricted simulator enabled the 80 qubit transfer. Trimming the state vector to reduce memory utilization lets the system mimic hundreds of qubits without affecting energy accuracy.

Prospects and availability

Amazon Braket now provides three Kvantify Qrunch licensing bundles. Basic is free and supports up to 35 qubits, whereas Pro and Enterprise offer infinite qubits, enhanced hardware access, and specialized scientific support.

Integrating quantum technologies for molecular simulations is a major step toward routine use. By enabling domain specialists to focus on chemistry rather than quantum infrastructure, Kvantify and AWS are speeding drug development and creating new carbon capture and enzymatic reaction materials.

Overview

Qiskit-Braket provider v0.11 improves integration between IBM's Qiskit framework and Amazon Braket's quantum computing service. This version lets users use Qiskit 2.0 with faster performance and more quantum application compatibility. Major innovations include Braket-specific primitives like the BraketEstimator and BraketSampler, which simplify data processing and circuit execution.

Circuit compilation has been simplified, making it easier for developers to translate and submit applications across quantum backends. Finally, this article provides a more flexible and powerful context for AWS quantum algorithm research and development. This content can help developers exploit these new open-source capabilities for advanced cloud-based quantum computing.

Release v0.11 of AWS Qiskit-Braket Provider

Amazon Web Services (AWS) improved its quantum computing integration tools with Qiskit-Braket provider v0.11. This latest version simplifies Amazon Braket quantum application development for developers. New “Primitives” aim to boost circuit composition and performance.

Quantum researchers increasingly use hybrid software environments to maximize quantum gear's capabilities, therefore the upgrading is crucial. By connecting Amazon Braket and IBM's Qiskit framework, v0.11 aims to give the global quantum community a “richer set of tools”.

Full Qiskit 2.0 integration

The formal support for Qiskit 2.0 is key to this release. This is a milestone because Qiskit 2.0 made major architectural changes, including deprecating some 1.x classes. The Qiskit-Braket supplier lets customers exploit the refactored codebase's speed gains by adopting this new standard.

Even as it adopts new technologies, AWS maintains backward compatibility for developers using existing systems. Since the v0.11 provider is compatible with 0.34.2, existing projects can continue while gradually implementing Qiskit 2.0.

Unlocking Flexible Circuit Compilation

One of this update's biggest technical improvements is to_braket. Manually moving circuits across frameworks was arduous. The supplier natively enables Qiskit transpile for flexible compilation features using this way.

To translate Qiskit, Braket, and OpenQASM3 inputs into Braket Circuit objects, use the flexible to_braket function. Amazon Braket devices can immediately receive these things. This flexibility supports Qiskit Targets and common transpilation inputs, creating wide compilation possibilities for Braket users who prefer the Qiskit interface.

Power of New Primitives

In v0.11, BraketEstimator and BraketSampler primitives are added. Although designed for Amazon Braket, these Qiskit primitives follow the same protocols as others.

Generic BackendEstimator and BackendSampler classes were simple wrappers allowing Braket executables to access backends. New native primitives give a key improvement:

Better Performance: Braket features accelerate and improve execution.

Enhanced Execution: Advanced parsing of generic PUBs, observables, and parameters.

Amazon Braket program sets enable efficient execution of several circuits, therefore the primitives are designed for them.

Developers may now use tasks to analyze aggregate ProgramSet objects.program_set to understand their runs. SparsePauliOps sum Hamiltonian observables and numpy-like array inputs are examples.

A Multidisciplinary Expert Group

AWS scientists and engineers collaborated on v0.11, reflecting quantum computing's transdisciplinary nature. Contributors include…

Cody Wang: A pianist and software engineer specializing on open-source libraries and quantum integrations. Senior product marketing manager Charunethran Panchalam Govindarajan holds a Stanford electrical engineering degree. Senior Product Manager Ishaan Pakrasi worked at the University of Illinois on engineering art and “dancing robots.”

Ryan Shaffer is an Applied Science Manager who works on quantum computer operation and verification. His PhD is in Physics from UC Berkeley.

Scott Smart: A University of Chicago Ph.D.-trained applied scientist who studies chemistry and quantum simulations.

In conclusion

Qiskit-Braket provider v0.11 improves AWS cloud availability for “quantum-enabled explorations” beyond a version upgrade. This version connects developers to more powerful quantum computing, whether they are Braket experts improving device-native compilation or Qiskit enthusiasts testing apps on new hardware.

This article examines quantum reservoir computing (QRC), a revolutionary machine learning method that uses Rydberg-atom quantum computers' complex dynamics. This approach processes data in a fixed physical reservoir, reducing training computing cost compared to conventional models. Quantum reservoir computing often outperforms neural networks in image classification and time series forecasting. The approach is robust and interpretable even with limited molecular datasets, showing its huge potential for pharmaceutical research. The source concludes that analog quantum technology can solve complicated problems that classical computers cannot.

Machine Learning's Quantum Leap: Rydberg Atom Reservoir Computing

Quantum Reservoir Computing (QRC) is a promising way for solving difficult problems on near-term quantum hardware in Quantum Machine Learning (QML). By using Rydberg-atom quantum computers' unique dynamics, QuEra Computing and Amazon Braket researchers demonstrated strong performance in image categorization and pharmaceutical research. This discovery opens the door to machine learning applications in areas where traditional methods fail, such as limited datasets or complex patterns.

Understanding Reservoir: Classical to Quantum

First, the reservoir computing paradigm must be understood to appreciate this study. This machine learning model links input signals and outputs using the temporal dynamics of a reservoir. The reservoir's parameters are fixed, unlike neural networks, where each link can be modified during training. Training is cheaper since just a basic readout layer needs to be taught to transform the reservoir's state to a desired output.

Even though Classical Reservoir Computing (CRC) processes data using chains of classical spins, quantum systems promise great potential. Using a quantum spin system as the reservoir, researchers can access a far broader state space than possible. This lets the program leverage entanglement and superposition to generate long-range quantum correlations for analyzing increasingly complex data patterns.

The Rydberg Atomic Mechanism

The researchers explain quantum reservoir computing using a Rydberg atom-based analog quantum computer. These atoms behave as two-level systems with customizable positions and are subject to “detuning,” which acts like a magnetic field. Three steps comprise the workflow:

Encoding: Atom insertion or detuning transforms image pixels into feature vectors for the Rydberg system. Quantum dynamics processes information as the system evolves. Researchers measure “local Pauli-Z observables,” a high-dimensional data-embedding vector, to train a classification algorithm.

Also see Hawking Radiation Can Amplify Quantum Links Near Black Holes.

Successful Image Classification and Prediction The researchers benchmarked quantum reservoir computing using the MNIST dataset of handwritten digits. QRC performed similarly to a four-layer feedforward neural network and reservoir approaches in a binary classification task (differentiating between 3 and 8). The real value came in more sophisticated scenarios, like diagnosing tomato diseases from leaf photographs.

QRC was more scalable than neural networks as the tomato disease test required up to 108 atoms to represent picture pixels. Increasing the number of measurement “shots” each data point substantially improved QRC accuracy, finally matching more complex classical models.

Quantum reservoir computing is great for time series forecasting and images because its processing power derives from physical system time dynamics. Researchers estimated laser chaotic light intensity most accurately using atom positions or “local detuning” to encode data. These methods offer a more complex configuration space and greater expressibility than “global” encoding methods, which may be limited by physical phenomena like thermalization.

Pharmaceutical Studies Advance

One of the biggest uses of quantum reservoir computing is pharmaceutical research. Sparse datasets hamper molecular property prediction, which is crucial to drug development. QRC-enhanced models outperformed baselines in Merck Molecular Activity Challenge dataset simulations with limited training records.

Although quantum reservoir computing embeddings were resilient with only 100 data, classical techniques' error rates climbed significantly as training samples decreased. UMAP visualization showed that QRC produced more understandable molecular activity clusters. Quantum reservoirs reveal chemical data patterns that traditional systems miss, making them essential for biological data analytics.

Overcoming Noise Challenges

Even with promising results, the researchers addressed experimental noise. Rydberg systems' quantum dynamics may be susceptible to “shot-to-shot” atom position fluctuations and thermalization over time, resulting in “lossy” data encoding. It shows that quantum reservoir computing is durable in particular parameter ranges, making it feasible for near-term quantum hardware despite these constraints.

Consideration of Future

Amazon Braket Introduces Quantum Processing Unit Spending Limits

AWS Spending Limit

Amazon Braket's new expenditure restriction function lets customers actively manage Quantum Processing Unit (QPU) prices. When studying quantum computing applications, research institutes, educational institutions, and development teams demanded better QPU expenditure control. This innovation quickly meets their needs.

With spending limitations, customers can set maximum device expenditure boundaries. Amazon Braket automatically checks task submissions against these caps. To avoid unintended overspending, jobs that exceed the budget are rejected before creation. Every AWS region that supports Amazon Braket now offers free expenditure constraints.

How Spending Limits Work A QPU device is linked to a maximum dollar amount to limit spending. When a limit is set, Braket tracks the device's total charges.

Amazon Braket verifies every task creation request against the limit. Braket immediately rejects and reports a validation error if a task's expected cost exceeds the expenditure limit.

The system estimates quantum work costs using the QPU list price and shot count. This predicted sum is removed from the expenditure cap when creating the job. Also, the system allows budget replenishment based on execution efficiency:

Using fewer successful shots than desired returns the unused anticipated cost to the expenditure limit.

Cancelling a task before completion returns the projected cost to the spending limit. Customers can modify spending caps as their needs change.

Governance of scope and cost

Users should know the full scope of this new feature: QPU cost limits apply only to on-demand quantum computations.

The feature excludes Amazon Braket-related costs like:

Simulators.

Managed notebooks.

Cases of hybrid jobs.

Braket Direct bookings produce quantum tasks.

Customers should continue using AWS Budgets as part of AWS Cost Control for comprehensive cost control across Amazon Web Services (AWS), including simulators and traditional compute components.

Additionally, consumers can limit their spending time. For managing AWS credits with expiration dates or ensuring payment cycles, this functionality restricts task submissions to the set interval.

Key Industry and Academic Applications

QPU expenditure caps benefit several key clientele groups:

Research Institutions and Budget Allocation: Research organisations must limit spending to manage quantum computing budgets across programs and clients. Pawsey Supercomputing Research Centre Chief Technology Officer Ugo Varetto underlined the necessity of having capabilities that allow their community of over 4,000 researchers to share budgets fairly and regulate costs. This prevents one workload from using unexpected research community resources. Research teams can set conservative bounds early on and change them for larger trials to minimise costly errors.

Education and Training: Amazon Braket lets educational institutions and training programs set spending caps that match course budgets for quantum computing courses. This prevents pupils from accidentally accumulating large charges and gives them practical experience with quantum devices. If a student mistakenly sets up a task with too many pictures, the spending limit stops the assignment and immediately reports the expenses.

Development Teams and Platform Builders: Quantum algorithm development teams benefit from spending caps during exploratory work. The Amazon Braket API allows companies that develop platforms based on Amazon Braket to programmatically set expenditure constraints for quantum computing and automatically enforce these restrictions on their customers.

Start-up and Resource Management Customers can set expenditure limits using the Amazon Braket Management Console, CLI, or SDK. The AWS CLI and SDK offer powerful automation and custom application integration methods.

Amazon Braket Management Console users can view QPU-specific expenditure limits in real time on a visual dashboard. This page displays the specified limit, current spending, queued spending (estimated device queue job expenses), and remaining spend. Due to this visibility, users may

Amazon Braket Introduces Quantum Processing Unit Spending Limits

AWS Spending Limit

Amazon Braket's new expenditure restriction function lets customers actively manage Quantum Processing Unit (QPU) prices. When studying quantum computing applications, research institutes, educational institutions, and development teams demanded better QPU expenditure control. This innovation quickly meets their needs.

With spending limitations, customers can set maximum device expenditure boundaries. Amazon Braket automatically checks task submissions against these caps. To avoid unintended overspending, jobs that exceed the budget are rejected before creation. Every AWS region that supports Amazon Braket now offers free expenditure constraints.

How Spending Limits Work A QPU device is linked to a maximum dollar amount to limit spending. When a limit is set, Braket tracks the device's total charges.

Amazon Braket verifies every task creation request against the limit. Braket immediately rejects and reports a validation error if a task's expected cost exceeds the expenditure limit.

The system estimates quantum work costs using the QPU list price and shot count. This predicted sum is removed from the expenditure cap when creating the job. Also, the system allows budget replenishment based on execution efficiency:

Using fewer successful shots than desired returns the unused anticipated cost to the expenditure limit.

Cancelling a task before completion returns the projected cost to the spending limit. Customers can modify spending caps as their needs change.

Governance of scope and cost

Users should know the full scope of this new feature: QPU cost limits apply only to on-demand quantum computations.

The feature excludes Amazon Braket-related costs like:

Simulators.

Managed notebooks.

Cases of hybrid jobs.

Braket Direct bookings produce quantum tasks.

Customers should continue using AWS Budgets as part of AWS Cost Control for comprehensive cost control across Amazon Web Services (AWS), including simulators and traditional compute components.

Additionally, consumers can limit their spending time. For managing AWS credits with expiration dates or ensuring payment cycles, this functionality restricts task submissions to the set interval.

Key Industry and Academic Applications

QPU expenditure caps benefit several key clientele groups:

Research Institutions and Budget Allocation: Research organisations must limit spending to manage quantum computing budgets across programs and clients. Pawsey Supercomputing Research Centre Chief Technology Officer Ugo Varetto underlined the necessity of having capabilities that allow their community of over 4,000 researchers to share budgets fairly and regulate costs. This prevents one workload from using unexpected research community resources. Research teams can set conservative bounds early on and change them for larger trials to minimise costly errors.

Education and Training: Amazon Braket lets educational institutions and training programs set spending caps that match course budgets for quantum computing courses. This prevents pupils from accidentally accumulating large charges and gives them practical experience with quantum devices. If a student mistakenly sets up a task with too many pictures, the spending limit stops the assignment and immediately reports the expenses.

Development Teams and Platform Builders: Quantum algorithm development teams benefit from spending caps during exploratory work. The Amazon Braket API allows companies that develop platforms based on Amazon Braket to programmatically set expenditure constraints for quantum computing and automatically enforce these restrictions on their customers.

Start-up and Resource Management Customers can set expenditure limits using the Amazon Braket Management Console, CLI, or SDK. The AWS CLI and SDK offer powerful automation and custom application integration methods.

Amazon Braket Management Console users can view QPU-specific expenditure limits in real time on a visual dashboard. This page displays the specified limit, current spending, queued spending (estimated device queue job expenses), and remaining spend. Due to this visibility, users may make educated decisions about workload management and restriction management.

Please note that recognized researchers can apply for AWS Cloud Credits for Research to support their Amazon Braket experiments. The Amazon Braket Spending limitations page is where customers should start using this service.

make educated decisions about workload management and restriction management.

AQT launches the IBEX Q1 Trapped-Ion Quantum Computer on Amazon Braket to boost European quantum access.

AQT, a leading quantum computer supplier from Innsbruck, Austria, has announced the availability of its IBEX Q1 trapped-ion quantum computer on Amazon Web Services (AWS) via Amazon Braket. This integration makes European quantum technology available to developers, government agencies, academic institutions, industrial firms, and research institutes globally via the cloud.

IBEX Q1 is a fully connected 12-qubit trapped-ion system. The Amazon Braket eu-north-1 Region (Stockholm) connects to the Innsbruck system.

Meeting Infrastructure and Sovereignty Needs

European clients need EU data residency while studying quantum computing uses, therefore the launch is notable. AQT's Austrian quantum computer is vital for consumers with data security, regulation, and technical sovereignty needs.

Eric Kessler, Amazon Braket's general manager, stressed that this geographic accessibility gives AWS clients greater alternatives and access to locally hosted infrastructure, satisfying sovereignty needs.

AQT CEO Thomas Monz was excited that the IBEX Q1 system on Amazon Braket gives European and overseas clients reliable and quick access to their high-performance trapped-ion quantum computers. He believes Braket and AQT's efforts will make this technology available worldwide, creating new value-creating applications.

IBEX Q1 Tech and Performance

Performance and infrastructure compatibility are incorporated into the IBEX Q1. The quantum computer's components fit within two 19-inch rack cabinets, complementing HPC and datacenter equipment. A complete quantum computer uses less than 2 kW of power at ambient temperature.

The IBEX Q1's trapped-ion architecture uses a calcium-40 ion crystal in an ultra-high vacuum chamber inside a radio frequency trap. The electronic spin state of charged atoms encodes quantum information.

Important architectural aspects include:

Universal connectivity: Regulating ion chain vibrations creates entangled gates. Thus, any system qubit can communicate directly with another.

Fully connected quantum algorithms often don't need SWAP gates to transfer quantum information. This increases circuit depth and error sources in less-connected systems.

The device's average two-qubit gate fidelity at launch is 97.7% for all qubit pairings. Native gates are RXX, RZ, and R. Regular automated calibration maintains quantum gates.

Applications and Access

Clients can access AQT's trapped-ion quantum computer from anywhere without infrastructure investments via the cloud. For dedicated capacity, Braket Direct allows hourly bookings or on-demand access.

IBEX Q1 is ideal for proof-of-concept use cases. AQT universal quantum computers are beneficial in many disciplines, including:

Chemistry

Portfolio optimisation

Risk assessment

Quantum safety

Benefits of Amazon Braket for AQT quantum computer access

Quantum computer cloud access anywhere: Direct cloud connectivity to AQT's trapped-ion quantum computer lets you employ quantum computing anywhere without infrastructure expenses.

Reserved or on-demand trapped-ion technology: Useful for research, education, industry, and prototyping to slowly introduce quantum applications.

AQT's universal quantum computers have been used in chemistry, risk analysis, portfolio optimisation, quantum security, cryptography, and more.

EU data residency: Innsbruck, Austria-based AQT's quantum computer IBEX Q1 is essential for enterprises and governments who need data protection, regulation, and technical sovereignty.

Encrypt/decrypt

For European customers, the device will be available Tuesdays and Wednesdays from 09:00 to 16:00 UTC.

New Amazon Braket Notebook Instances Natively Support NVIDIA CUDA-Q, Revolutionising Quantum Development on AWS

An important quantum computing platform upgrade from AWS is that Amazon Braket Notebook settings now natively support CUDA-Q, NVIDIA's open-source hybrid quantum-classical computing architecture. Increasing NVIDIA's accessibility streamlines hybrid quantum-classical system developers' and scholars' workflows.

The connection lets customers run CUDA-Q programs in Amazon Braket Jupyter notebook instances without configuration. Native support is enabled by upgrading laptop instances to Amazon Linux 2023, which improves security, performance, and compatibility for quantum development workflows.

Smooth Hybrid Workflow Development

With this intrinsic feature, quantum researchers and developers can simply create and test hybrid quantum-classical algorithms. The platform simplifies hybrid algorithm creation, modelling, and execution in Braket-managed notebooks.

Native CUDA-Q support provides several key features:

GPU-accelerated calculations and quantum simulations can be combined in hybrid workflows. GPU acceleration: Amazon Braket makes NVIDIA GPUs available to developers for faster algorithm creation and simulation.

Access to Quantum Hardware: The platform lets users simply switch from simulation to Braket's quantum hardware. IonQ, Rigetti, and IQM offer single-managed Quantum Processing Units (QPUs). Amazon This release strengthens Braket's position as a comprehensive quantum computing research and development platform. It simplifies CUDA-Q use in managed notebooks by eliminating the need for developers to control local deployment or route execution via Hybrid Jobs.

New Environment Access and Pre-Installed Packages When customers create an Amazon Braket notebook instance, they get the latest kernel. New conda_braket tile may appear when you open the notebook. By selecting this tile under “Notebook” or “Console,” the new conda_braket kernel launches a Jupyter notebook or Python console session.

“CUDA-Q and Braket” tile opens example notebooks using the conda_braket kernel as the default kernel.

Braket notebooks come with the latest compatible packages for the four leading quantum development frameworks Braket, CUDA-Q, PennyLane, and Qiskit. Developers can verify installed packages with a command.

Several critical package versions are confirmed in the output, including:

Amazon Basket Algorithm Library 1.6.2

amazon-braket-default-simulator=1.31.4

Amazon-braket-pennylane-plugin=1.33.5

Amazon-braket-schemas=1.26.1

Amazon-braket-sdk=1.102.6

cudaq=0.12.0.post1

cudaq-qec=0.4.0.post1

cudaq-solvers=0.4.0

PennyLane=0.42.3

PennyLane_Lightning=0.42.0

1.4.4 qiskit

0.17.2 qiskit-aer

Qiskit-algorithms=0.4.0

qiskit-ionq=0.6.1

0.6.0 qiskit_braket_provider

Amazon Braket notebook instances come with quantum applications using Braket, CUDA-Q, PennyLane, and Qiskit. Users can view CUDA-Q examples on the Launcher page by clicking “CUDA-Q and Braket”. This opens the notebook 0_hello_cudaq_jobs.ipynb and shows more examples under nvidia_cuda_q/.

How to Implement and Examples

Small, CPU-based instance types like ml.t3.medium are recommended for laptop instances by AWS. Amazon Braket Hybrid Jobs can perform GPU-intensive CUDA-Q apps. GPU-powered instances like ml.p3.8xlarge are recommended for these intensive tasks. GPU-accelerated instances include:

ml.p3.2xlarge (1 NVIDIA V100 GPU).

ml.p3.8xlarge (4 V100 GPUs).

ml.p3.16xlarge (8 V100 GPUs).

When running GPU-powered instances concurrently through Hybrid Jobs, a customer's Amazon Elastic Compute Cloud (EC2) service quota should exceed the number of instances they want.

The Previous Docker-Based Setup

Developers needed a Jupyter kernel running a CUDA-Q Docker container to execute CUDA-Q apps interactively in Braket notebooks before this native integration. This enables customers to run CUDA-Q simulators on Amazon Braket-supported quantum hardware backends and powerful NVIDIA GPUs using the open-source NVIDIA CUDA-Q platform and Amazon Braket Hybrid Jobs.

Braket Notebook instances come with Docker, allowing controlled development using NVIDIA NGC Container Registry images.

The previous approach required several steps to configure a custom kernel:

Dockerfile creation: Stable Dockerfiles require CUDA-Q images like nvcr.io/nvidia/quantum/cuda-quantum:cu12-0.9.1. This file explained installing ipython, ipykernel, and amazon-braket-sdk.

Next, the image was built in three to five minutes.

For the new kernel (such as docker_cudaq), a kernel.json file was created containing command-line options for starting the kernel with the newly created Docker image.

GPU Access: Add “–gpus=all” to the kernel to access GPU instances like ml.p3.2xlarge, ml.p3.8xlarge, and ml.p3.16xlarge in CUDA-Q program.configuration in JSON.

This configuration mounts /home/ec2-user/amazon-braket-examples/examples inside the CUDA-Q container. If they needed more Python modules or updated CUDA-Q versions, they merely needed to tweak the Dockerfile and rebuild the Docker image.

Hamiltonian Embedding: A Quantum Method for Simulating High-Dimensional Dynamics on Near-Term Hardware

A team of researchers from the University of Maryland and the University of California, Berkeley created Hamiltonian embedding to bridge the gap between near-term quantum hardware limits and complicated computational difficulties. This method makes it easier to simulate high-dimensional dynamics governed by partial differential equations (PDEs) that classical computers cannot solve.

Scientists and engineers in fluid dynamics, aircraft design, and heat and sound propagation need PDE simulation. Due to the exponential computer difficulty of solving high-dimensional differential equations, classical skills are severely limited. Many PDEs have been solved using quantum methods, but most require complicated input models like block-encoded matrices and Quantum Random Access Memory (QRAM), which require massive, fault-tolerant quantum computers that are not currently accessible.

Connecting Local Hardware to Complex Issues

To simulate differential equations on qubit-based quantum computers, discretise them. Researchers use finite difference to study first- and second-order differential operators. After discretisation, the finite-dimensional issue Hamiltonian converts the differential equation to quantum dynamics. Free particles follow the Schrödinger equation.

Problem Hamiltonian (up to negative sign) is a tridiagonal matrix with main diagonal components Hj,j = -2h-2 and sub/super diagonal elements Hj,j+1=Hj+1,j=h-2. Many differential equation Hamiltonians are sparse, banded matrices like tridiagonals.

A quantum computer that accurately simulates Hamiltonian time development without overhead is ideal. Current quantum computers use local spin operators (Pauli matrices) and allow only local qubit interactions. Qubit operator representations of sparse matrices may need considerable non-local interaction terms.

Researchers can simulate differential equations on quantum devices via Hamiltonian embedding. Translating the problem Hamiltonian to an embedding Hamiltonian (local spin operators) that physical hardware can better simulate is the main notion. The block-diagonal decomposition of a local spin operator embedding Hamiltonian H is H = diag(A,), where A is embedded in the upper left corner. By simulating H's temporal development on a quantum computer—presumably easier than simulating A—we implement A's evolution in the upper left corner e-iHt=diag(e-iAt,). The following example demonstrates.

Consider an 8-by-8 binary matrix A, with all zeros except for A1,8=A8,1=1 and Aj,j+1=Aj+1,j=1 for j = 1,…,7.

Circulant matrix is a simple Laplace operator with periodic boundary conditions. Three-qubit Hamiltonian A is used in quantum computing. A is basic, but block-encoding it as a quantum circuit is challenging and may take multiple qubits. Breaking A into fundamental Pauli strings produces various component operators, including 3-qubit interactions like XXX. Basic Hamiltonians are difficult for quantum computers to simulate.

As an alternative, Hamiltonian embedding represents A using simple quantum operations. Sx=X1+X2+X3+X4 is a 4-qubit Hamiltonian with Xj as a Pauli-X operator on site j. Hamiltonian Hilbert space has basis. Next, analyse Table 1's basis' 8-dimensional circulant unary code subspace:

The Hamming distance between adjacent codewords (including 1 and 8) is always 1, hence projecting Sx onto this subspace yields its target matrix A. By setting an initial state in this subspace and penalising leaking outside of it, A can be quantum mimicked without ancilla qubits using a few fundamental gates or analogue evolution time. Researchers disregard measurement findings outside the relevant subspace after selecting them. Other embedding procedures can fix this with antiferromagnetic or one-hot codes. For Hamiltonian embedding details, see the original work.

Also see Double-Transmon Coupler Improves Superconducting Quantum.

Successful Amazon Braket Device Demos Jiaqi Leng, Joseph Li, and Xiaodi Wu demonstrated Hamiltonian embedding's effectiveness on Amazon Braket's IonQ and QuEra quantum computing architectures.

Spatial discretisation was employed to model a two-dimensional Schrödinger equation's dynamics, generating a N2-sized problem Hamiltonian. To complement the QuEra device's Rydberg Hamiltonian (HRyd) architecture with positive Rydberg interaction coefficients (Vij), an antiferromagnetic embedding technique was devised.

This encoding method translates the problem Hamiltonian Hprob to the machine Hamiltonian HRyd by carefully selecting parameters and atom locations. The experiment employed 12 qubits in two chains (one for each spatial variable, x and y) with a discretisation number N=7. Despite hardware noise, experimental results matched numerical simulations qualitatively.

IonQ 1D Bosonic Dynamics Simulation

A one-dimensional Schrödinger equation for a single bosonic mode was simulated using IonQ's 25-qubit trapped ion quantum computer in another experiment.

In this case, Fock space truncation transferred the physical Hamiltonian to a finite-dimensional tridiagonal matrix. One-hot embedding applied this to IonQ. This embedding Hamiltonian featured up to 2-body interaction terms, making it suitable for near-term devices.

The Hamiltonian's “diagonal part” was handled by parameterised single-qubit Z rotations, while the “off-diagonal” part was implemented by the IonQ native Mølmer–Sørensen gate The Hamiltonian embedding framework can simulate a d-dimensional Schrödinger equation using O(d) qubits and polynomial interaction terms in d, giving an exponential quantum advantage over mesh-based PDE simulation.

Although noisy gates caused errors, the trials accurately recorded the position and kinetic energy operators' oscillating behaviour, matching theoretical closed-form solutions.

You may read IonQ in DARPA Quantum Computing QBI Program Stage B.

The world's leading quantum computer manufacturer, IQM Quantum Computers, updated its IQM Resonance cloud platform. This big development uses new software tools to speed up quantum algorithm generation and give customers a more resilient and expanded quantum system. IQM is known for its on-premises full-stack quantum computers and cloud platform, serving top high-performance computing  centres, research labs, universities, and enterprises worldwide. Over 300 individuals work for the Finnish company, which has a global presence on numerous continents.

Key IQM Resonance platform updates and features include:

Novel 54-Qubit Quantum Computer: An advanced Crystal 54 processor powers the platform's 54-qubit quantum computer. Amazon Web Services' quantum computing service, Amazon Braket, should offer this dependable system by July 16, 2025. Providing the quantum community with high-qubit counts is a major advance.

The default SDK for the IQM Resonance platform is Qrisp, an open-source project started by Fraunhofer FOKUS. Qrisp offers a strong and easy-to-learn higher-level programming interface for quantum developers and researchers. To give users options, IQM will support Qiskit, Cirq, Cuda Quantum, and TKET when Qrisp becomes the main SDK. This thorough and open quantum development approach gives beginners and experts a firm foundation. IQM also hired Raphael Seidel, Qrisp's Lead Quantum Software Engineer, to lead its development in October 2025, a major move.

Seidel stressed that Qrisp's programming methodology routinely delivers “serious performance advantages”. He called Qrisp “state-of-the-art in quantum programming” and said its direct and robust integration into IQM's quantum hardware will give it a “strong head-start into the era of fault-tolerant quantum computers.”

Advanced Error Handling: The platform now supports all error-reducing techniques. Dynamical decoupling was one of the first qubit noise protection features. The next step is to reduce readout error to considerably improve experimental precision. These advances are crucial for consumers to acquire more reliable quantum computation data.

A powerful Quantum Approximate Optimisation Algorithms (QAOA) library accelerates research. This crucial application library allows speedy iteration on new concepts and the research of unique quantum algorithms with its many QAOA flavours. It also helps researchers develop, test, and adjust quantum circuits for complex optimisation difficulties.

Expanded IQM Academy Resources: To suit the latest upgrades, materials have been considerably upgraded. In-depth Qrisp examples and tutorials and an error reduction section have been included. The academy will soon offer a Qrisp on IQM hardware lecture series and insights into IQM's upcoming Noise Robust estimation methods.

IQM Resonance now offers pulse-level access for experienced users that need maximum experimental control. Scientists can directly program pulse patterns to create novel quantum operations and precise experiments.

Increased Access and Adoption:

IQM is offering a free "Starter tier" with up to 30 credits per month on some quantum computers to increase access to its top platform. This project aims to boost quantum technology interest by decreasing barriers for new researchers, developers, and students. With the launch of this Starter Tier and the rapid availability of IQM Crystal 54, IQM is also giving all Starter tier customers temporary access to the 54-qubit quantum computer to encourage experimentation and creativity.

Dr. Stefan Seegerer, IQM's Head of Product, Quantum Platform, called these achievements “a new era of utility for quantum computing” and showed the company's commitment to ecosystem enablement. He stressed that IQM is providing researchers and developers with the Crystal 54-qubit system, cutting-edge error reduction techniques, and Qrisp standardisation to push the frontiers of what is possible in the sector. Dr. Seegerer called the free Starter package a “crucial step in our mission to make quantum technology accessible to everyone.”