Our Technology

Explore the patent-pending technology behind Quantonic's hybrid photonic-classical computing platform. 16 detailed technical diagrams showing system architecture, photonic processing, and educational interface.

Patent Pending: AU 2025/2025234266

Our Technology

The QL-series platform combines photonic quantum processing with classical acceleration through a patent-pending hybrid architecture. Below are technical diagrams from our patent application illustrating key system components.

System Architecture

Figure 1

System Architecture Overview

High-level overview of the QL-series hybrid photonic-classical computing platform, showing the integration between classical processing units and the photonic subsystem.

Figure 2

Photonic Processing Unit

Detailed architecture of the photonic processing unit (PPU) showing Mach-Zehnder interferometer mesh and optical pathways.

Figure 3

Hybrid Execution Model

Workflow diagram illustrating how computations are partitioned between classical and photonic processors for optimal performance.

Figure 4

AI-Augmented Circuit Partitioning

Machine learning engine that dynamically determines optimal workload distribution between classical and quantum subsystems.

Figure 5

Optical Interconnect Architecture

Silicon photonics-based interconnect system enabling high-bandwidth, low-latency communication between processing elements.

Figure 6

Quantum State Preparation

Single-photon source array and state preparation circuits for initializing quantum computations.

Figure 7

Measurement and Readout

Single-photon detector array and classical post-processing pipeline for quantum measurement results.

Platform Infrastructure

Figure 8

Multi-Tenant Architecture

Software architecture enabling concurrent access for 100+ users while maintaining isolation and fair resource allocation.

Figure 9

Error Mitigation Pipeline

Real-time error detection and mitigation techniques for maintaining computational fidelity in the photonic subsystem.

Figure 10

Thermal Management System

Passive and active cooling architecture maintaining room-temperature operation without cryogenic requirements.

Figure 11

Control Electronics

FPGA-based control system managing photonic component timing, phase control, and detector synchronization.

Software & User Experience

Figure 12

Software Stack

Layered software architecture from low-level hardware abstraction to high-level quantum programming interfaces.

Figure 13

Desktop Form Factor

Physical enclosure design optimized for laboratory deployment with standard rack-mount compatibility.

Figure 14

Quantum Algorithm Workflow

End-to-end workflow for executing quantum algorithms, from high-level description to photonic circuit compilation and execution.

Figure 14A

Circuit Compilation Pipeline

Detailed view of the quantum circuit compilation process, transforming abstract quantum operations into photonic gate sequences.

Figure 15

Educational Interface

Multi-tenant user interface designed for educational environments, enabling concurrent student access with progress tracking and curriculum integration.

Our Technology

Our Technology

System Architecture

System Architecture Overview

Photonic Processing Unit

Hybrid Execution Model

AI-Augmented Circuit Partitioning

Optical Interconnect Architecture

Quantum State Preparation

Measurement and Readout

Platform Infrastructure

Multi-Tenant Architecture

Error Mitigation Pipeline

Thermal Management System

Control Electronics

Software & User Experience

Software Stack

Desktop Form Factor

Quantum Algorithm Workflow

Circuit Compilation Pipeline

Educational Interface

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