Quantum Noise Parameter Calculator

Calculator Inputs

Use practical detector values. Large screens show three columns. Smaller screens show two or one column automatically.

Optical Power (mW)

Wavelength (nm)

Measurement Bandwidth (MHz)

Quantum Efficiency (0 to 1)

Dark Current (nA)

Load Temperature (K)

Load Resistance (Ω)

Excess Noise Factor

Squeezing Variance Factor

Reset

Plotly Graph

The graph shows RMS current components in nanoamps. It switches to example mode before calculation.

Example Data Table

Scenario	Power (mW)	Wavelength (nm)	Bandwidth (MHz)	η	F	S	Q Parameter	Noise (dB)	Total RMS (nA)	State
Balanced reference detector	0.80	1,064.00	5.00	0.90	1.00	1.00	1.822845	2.6075	42.4799	Above shot-noise limit
Cooled low-dark photodiode	1.20	1,310.00	10.00	0.88	1.00	0.85	1.385484	1.4160	70.3810	Above shot-noise limit
Avalanche receiver path	0.50	850.00	20.00	0.76	2.40	1.00	6.369411	8.0410	103.1224	Above shot-noise limit

Formula Used

This calculator models detector noise against the shot-noise reference. The reported quantum noise parameter is a normalized variance ratio.

Photon Energy: E = h c / λ

Photon Rate: Φ = P / E

Responsivity: ℜ = η q λ / (h c)

Photocurrent: I_ph = ℜ P

Shot-Noise SQL Variance: σ_SQL² = 2 q I_ph B

Used Shot Variance: σ_shot² = S × σ_SQL²

Dark Variance: σ_dark² = 2 q I_d B

Carrier Variance: σ_carrier² = F × (σ_shot² + σ_dark²)

Thermal Variance: σ_thermal² = 4 k T B / R

Total Variance: σ_total² = σ_carrier² + σ_thermal²

Quantum Noise Parameter: Q = σ_total² / σ_SQL²

Noise in dB: Q_dB = 10 log₁₀(Q)

A value near 1 indicates shot-noise-limited behavior. Values above 1 show excess noise. Values below 1 suggest sub-shot-noise operation when squeezing dominates.

How to Use This Calculator

Enter optical power in milliwatts.
Provide the detector wavelength in nanometers.
Set your measurement bandwidth in megahertz.
Enter quantum efficiency as a decimal from 0 to 1.
Add dark current, temperature, and load resistance values.
Use excess noise factor above 1 for avalanche behavior.
Use squeezing factor below 1 for reduced quantum variance.
Press the calculate button to view results above the form.
Review the graph, table values, and detector classification.
Download the result set as CSV or PDF.

Frequently Asked Questions

1. What does the quantum noise parameter represent?

It compares total measured variance with the shot-noise reference. A value of 1 means ideal shot-noise-limited behavior. Larger values show extra noise sources.

2. What does a value below 1 mean?

A result below 1 indicates sub-shot-noise performance. This usually appears when squeezed states reduce optical variance more than other noises add back.

3. Why is wavelength included?

Wavelength changes photon energy and detector responsivity. Those terms directly affect photon rate, photocurrent, and the reference shot-noise level.

4. Why does bandwidth increase noise?

Shot, dark, and thermal noise all grow with measurement bandwidth. Wider bandwidth captures more fluctuations, so RMS noise becomes larger.

5. When should I change the excess noise factor?

Increase this factor for devices with multiplication noise, such as avalanche photodiodes. Leave it at 1 for simple photodiodes without excess gain noise.

6. What is the squeezing variance factor?

It scales the optical shot variance. Use 1 for ordinary coherent light. Use values below 1 when squeezed light reduces quantum fluctuations.

7. Can this page replace a full detector simulator?

No. It is a fast engineering estimator. It ignores frequency-dependent electronics, saturation, impedance mismatches, and many device-specific nonlinear effects.

8. Which units should I enter?

Enter power in mW, wavelength in nm, bandwidth in MHz, dark current in nA, temperature in K, and resistance in ohms.