Xanadu Strawberry Fields. Our latest paper, Continuous-variable quantum neural networks, u
Our latest paper, Continuous-variable quantum neural networks, uses Strawberry Fields to The PennyLane-SF plugin integrates Xanadu's Strawberry Fields photonic quantum simulators and hardware with PennyLane's quantum machine Design, simulation, and hardware execution of these variational circuits is handled by Xanadu’s PennyLane package. An API key is required to One of the advantages of PennyLane is that it can be run on many different simulators and real quantum devices from a variety of external providers through our Plugins, Strawberry Fields is a full-stack Python library for designing, optimizing, and utilizing photonic quantum computers. Introduction ¶ Strawberry Fields is an open-source framework for photonic quantum computing. Implemented in Python for ease-of-use, Strawberry Fields is specifically targeted to continuous The TDMProgram ¶ Rather than performing the mode shifting and sample reshaping manually, Strawberry Fields provides the TDMProgram As part of these efforts, we are thrilled to announce a new addition focused on algorithms for near-term devices: the Strawberry Fields applications (apps) layer 🎉. It also includes a function for sampling more We introduce Strawberry Fields, an open-source quantum programming architecture for light-based quantum computers, and detail its key features. We introduce Strawberry Fields, an open-source quantum programming architecture for light-based quantum computers, and detail its key features. Design To get started with writing your own Strawberry Fields code, begin with our photonic circuit quic Next, read more about using Strawberry Fields with photonic hardware, including code demonstrations and an overview of Xanadu's quantum photonic hardware. To begin, we create the boson Strawberry Fields: A Software Platform for Photonic Quantum Computing Using Strawberry Fields to simulate quantum teleportation from scratch. Before you begin, be To see Strawberry Fields in action immediately, try out our Strawberry Fields Interactive web application. Strawberry Fields is a full-stack Python library for constructing, simulating, and executing programs on photonic quantum computers. The GBS applications layer includes functions for sampling from GBS devices that are programmed in this manner. Use Strawberry Fields to build and submit quantum programs for execution on next-gen photonic hardware. Prepare your initial states, drag and drop gates, and watch your Strawberry Fields is a full-stack Python library for designing, simulating, and optimizing continuous-variable quantum optical circuits. Xanadu Located in the heart of downtown Toronto, we've brought together exceptional minds from around the world to build quantum computers that are useful and available to people everywhere. Strawberry Fields is a full-stack Python library for designing, simulating, and optimizing continuous-variable quantum optical circuits. hbar at the beginning of a session. These operations are used to Strawberry Fields relies on classical simulation to evaluate cost functions of the CV quantum neural network and the resultant gradients with respect to parameters of each layer. """ The Strawberry Fields codebase includes a number of complementary components. However, Strawberry Fields, Xanadu's Python library, simulates these with exact Gaussian backends (polynomial time) and approximate Fock backends for non-Gaussian gates like In a previous tutorial we introduced the basics of time-domain photonic circuits — the same technology underpinning Xanadu’s quantum computational advantage hardware Abstract We introduce Strawberry Fields, an open-source quantum programming architecture for light-based quantum computers, Simulating this circuit using Strawberry Fields is easy; we can simply read off the gates from left to right, and convert it into the Blackbird circuit language. Operations ¶ Strawberry Fields supports a wide variety of photonic quantum operations — including gates, state preparations and measurements. In particular, Strawberry Fields allows for the following workflows: Construct and simulate Xanadu Located in the heart of downtown Toronto, we've brought together exceptional minds from around the world to build quantum computers that are useful and available to people everywhere. Strawberry Fields integrates seamlessly with the Xanadu Quantum Cloud. He works on the photonics Getting started To get started with writing your own Strawberry Fields code, begin with our photonic circuit quickstart guides, before Hardware and cloud ¶ Using Strawberry Fields, you can submit quantum programs to be executed on photonic hardware or to be run on a cloud simulator via the Xanadu Cloud. In Strawberry Fields we use the convention \ (\hbar=2\) by default, but other conventions can also be chosen by setting the global variable sf. with \ (k = \sum_ {i}s_ {i}\). Execute photonic quantum algorithms directly on In this tutorial, we demonstrate how Strawberry Fields can execute quantum programs on the X8 family of remote photonic devices, via the Xanadu Using Strawberry Fields, you can submit quantum programs to be executed on photonic hardware or to be run on a cloud simulator via the Xanadu Cloud. The following tutorials showcase using Strawberry Fields to execute quantum programs on Xanadu’s quantum photonic hardware. Strawberry Fields focuses on About the authors ¶ Theodor Isacsson Theodor Isacsson is a quantum software developer at Xanadu. Built in Python, Strawberry # See the License for the specific language governing permissions and # limitations under the License. Built in Python, Strawberry Fields is a . Behind the scenes, Strawberry Fields is an integral part of our research workflow. The first import statement imports Strawberry Fields as sf, allowing us to access the engine and backends; the second import statement imports all Strawberry Fields is a full-stack Python library for designing, optimizing, and utilizing photonic quantum computers. Strawberry Fields is a full-stack Python library for designing, optimizing, and utilizing photonic quantum computers.
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