Superconducting QPU

Experience the pinnacle of quantum computing hardware. Our superconducting quantum processors deliver 1000+ qubits, 99.9%+ gate fidelities, and coherence times exceeding 500 microseconds. Built for enterprise applications that demand uncompromising performance and reliability.

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Technical Specifications

1024
Qubits
All-to-all connectivity
99.95%
2-Qubit Gate Fidelity
CNOT, CZ gates
99.99%
1-Qubit Gate Fidelity
X, Y, Z rotations
500μs
T2 Coherence
Echo coherence time
250μs
T1 Relaxation
Energy relaxation time
30ns
Gate Duration
Single-qubit gates
99.5%
Readout Fidelity
State discrimination
500ns
Readout Time
Simultaneous readout
99.9%
Uptime SLA
Enterprise reliability

Architecture & Design

[VIDEO: 3D visualization of superconducting QPU architecture - qubit layout, control lines, readout resonators]

Our QPU features a heavy-hexagon lattice topology with transmon qubits. Each qubit connects to 6 neighbors, enabling efficient circuit compilation. Dilution refrigerator maintains base temperature of 15mK for optimal coherence.

Transmon Qubits

Fixed-frequency transmon qubits with capacitive coupling. Josephson junctions fabricated using electron-beam lithography for precision. Typical frequency: 5-6 GHz, anharmonicity: 200-300 MHz.

  • Charge noise insensitivity
  • Long coherence times
  • Simple control architecture
  • Scalable fabrication

Control Electronics

Custom FPGA-based control system with low-latency feedback. 10 GSPS DACs for pulse shaping, real-time calibration, and mid-circuit measurement. Supports dynamic circuits and quantum error correction.

  • Arbitrary waveform generation
  • Real-time feedback (<1μs)
  • Parallel qubit control
  • Error correction support

Readout System

Dispersive readout using Josephson parametric amplifiers (JPAs) for near-quantum-limited amplification. Multiplexed readout enables simultaneous state measurement of all qubits with minimal crosstalk.

  • Quantum-limited amplification
  • High fidelity discrimination
  • Fast measurement (500ns)
  • Low crosstalk (<0.1%)

Calibration & Maintenance

Automated Characterization

[IMG: Calibration dashboard showing qubit parameters, gate fidelities, and error rates updated in real-time]

Continuous Calibration

Automated calibration routines run continuously in background. Qubit frequencies, gate pulses, and readout parameters optimized every hour to maintain peak performance.

Gate Optimization

DRAG pulse shaping minimizes leakage errors. Optimal control theory (GRAPE, CRAB) designs high-fidelity gates. Each gate characterized via randomized benchmarking.

Crosstalk Mitigation

Comprehensive crosstalk characterization identifies unwanted interactions. Simultaneous randomized benchmarking measures correlated errors. Pulse schedules optimized to minimize crosstalk.

Predictive Maintenance

Machine learning models predict component failures before they occur. Automated alerts trigger preventive maintenance. 99.9% uptime guaranteed through proactive monitoring.

Error Characterization

Full tomographic characterization of quantum processes. Gate set tomography, process tomography, and noise spectroscopy identify error sources. Data used to improve error mitigation.

Benchmarking

Daily benchmarking with randomized benchmarking, cross-entropy benchmarking, and application-specific metrics. Public reports ensure transparency and accountability.

Ideal Applications

Quantum Chemistry

Simulate molecular systems with chemical accuracy. VQE calculations for ground state energies, excited states, and reaction pathways. Supports molecules with 50+ orbitals. Pharmaceutical and materials science applications.

Optimization Problems

Solve QUBO and Ising problems using QAOA and VQE. Portfolio optimization, logistics, scheduling, and resource allocation. Outperforms classical methods for NP-hard problems at scale.

Machine Learning

Quantum neural networks, variational classifiers, and kernel methods. Feature mapping to high-dimensional Hilbert spaces for enhanced learning capacity. Hybrid quantum-classical training pipelines.

Cryptography

Quantum random number generation for cryptographic keys. Shor's algorithm demonstrations for educational purposes. Post-quantum cryptography algorithm testing and validation.

Financial Modeling

Option pricing, risk analysis, and portfolio optimization. Quantum amplitude estimation for Monte Carlo acceleration. Credit risk assessment and fraud detection applications.

Research & Development

Algorithm research, error correction experiments, and quantum advantage demonstrations. Ideal platform for academic research and quantum software development.

Technology Comparison

Metric Ishara Superconducting Trapped Ion Photonic
Gate Fidelity 99.95% 99.9% 99%
Gate Speed 30-100ns 10-100μs 1ns
Qubit Count 1024 32 256
Connectivity Heavy-hex (6-neighbor) All-to-all Limited
Coherence Time 500μs 50s N/A (flying qubits)
Operating Temp 15mK (dilution fridge) Room temp (trap) Room temp
Scalability Excellent Challenging Good
Error Correction Excellent support Good support Limited

Access Quantum Hardware

Join leading enterprises and research institutions leveraging our superconducting QPUs. Cloud access available now. On-premise installations for security-critical applications.

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