Dirac-3
What is Dirac-3?
In quantum information processing, loss and noise are often detrimental and must be minimized. This is why quantum systems using atomic qubits (and similar) must be kept in cryogenic vacuum chambers, and why photon loss is the main obstacle to quantum communications and computing. This requirement poses enormous challenges in the fabrication and operation of quantum systems and has been the bottleneck preventing the scaling of the number of qubits and their connectivity.
With entropy-based quantum computing, we're turning the tables. Instead of trying to avoid loss and noise, we're harnessing them to build quantum machines whose capacity and speed surpass existing computing methods.
This radically new approach is called Entropy Quantum Computing (EQC) . It is deeply based on fascinating principles of quantum mechanics:
First, the loss or decoherence of a quantum state occurs due to its coupling to an entropy source with many degrees of freedom. The apparent disappearance of quantum characteristics is merely a statistical average of many possible outcomes of such coupling.
Second, the vacuum is never silent, even though it appears to contain neither energy nor particles. In fact, there are enormous amounts of random fluctuations constantly occurring in each of the vacuum's modes.
EQC was conceived and developed based on these quantum principles. Instead of creating and manipulating pure qubits isolated from their surroundings, EQC uses loss and decoherence , transforming entropy into the high-power fuel for its computational engine.
In stark contrast to any existing quantum platform, it requires no cryogenics or isolation , and can be implemented using integrated photonics, resulting in SWAP-C (space, weight, power, and cost) compliant devices, such as common PCs.
It has an approximate value in Chile of USD 350,000https://quantumcomputinginc.com/products/commercial-products/dirac-3
