Resonator & Coupling

Resonator & Coupling Parameters: Readout and bus resonator characteristics plus

qubit-resonator coupling extracted via EPR

  1. Resonator Properties

Parameter

Symbol

Unit

Description

Optimal / Best Value

Good Range

Acceptable Range

Poor / Worst Value

Physical Significance

Resonator Frequency

omega_r / 2pi

GHz

Bare resonator frequency; should be detuned from qubit to remain in

dispersive regime.

6.5 – 8.5 GHz

5 – 10 GHz

3 – 5 GHz

< 2 GHz

Must satisfy |Δ| = |ω_q - ω_r| >

> g for dispersive approximation; EPR gives bare frequency.

Resonator Internal Q

Q_int

dimensionless

Internal (material-limited) quality factor of the readout resonator.

> 10⁵

10⁴ – 10⁵

10³ – 10⁴

< 500

Low Q_int adds photon loss increasing measurement back-action and

reducing readout SNR.

Resonator External Q

Q_ext

dimensionless

External quality factor set by coupling to transmission line; determines

measurement bandwidth.

10³ – 10⁴ (fast readout)

500 – 2×10⁴

50 – 499

< 50

Too high → slow readout; too low → Purcell-enhanced qubit decay.

Optimized with Purcell filter.

Resonator–Qubit Detuning |Δ|

|Δ|/2π

GHz

Frequency detuning between qubit and resonator; must be large compared

to coupling g.

1.0 – 3.0 GHz

0.5 – 4.0 GHz

0.1 – 0.5 GHz

< 0.05 GHz

Small detuning violates dispersive approximation; EPR hybridization

factor chi tracks this.

Purcell Decay Rate

γ_P/2π

kHz

Qubit decay rate via resonator Purcell channel; κ * (g/Δ)². Must be

< < 1/T1_target.

< 1 kHz

1 – 10 kHz

10 – 100 kHz

> 500 kHz

Dominant T_1 limit in many designs without Purcell filter; directly

predicted by EPR p_J^res.

  1. Coupling Strengths

Parameter

Symbol

Unit

Description

Optimal / Best Value

Good Range

Acceptable Range

Poor / Worst Value

Physical Significance

Transverse Coupling g / 2pi

g / 2pi

MHz

Qubit-resonator coupling strength (Jaynes-Cummings); extracted from EPR

as g = √(p_J^res * ω_r * ω_q / 2).

50 – 150 MHz

20 – 200 MHz

5 – 19 MHz

< 2 MHz

Sets χ and readout speed; g/|Δ| < 0.1 required for dispersive

regime.

Dispersive Coupling g/Δ ratio

g/|Δ|

dimensionless

Dimensionless ratio quantifying proximity to strong-coupling limit; must

be < < 1 for dispersive readout.

0.01 – 0.05

0.005 – 0.09

0.09 – 0.15

> 0.20

Ratio > 0.1 causes photon-number-dependent qubit dephasing and

higher-order dispersive corrections.

Bus Coupler Coupling (2Q)

J / 2pi

MHz

Exchange coupling between two qubits via bus resonator or direct

capacitance.

5 – 20 MHz

2 – 30 MHz

0.5 – 1.9 MHz

< 0.1 MHz

Too weak → slow two-qubit gates; too strong → residual ZZ. EPR predicts

J from geometry.

Residual ZZ (static)

zeta_ZZ / 2pi

kHz

Always-on longitudinal (ZZ) qubit–qubit interaction; source of

conditional phase errors.

< 10 kHz

< 100 kHz

100 – 500 kHz

> 1 MHz

Limits two-qubit gate fidelity via conditional phase accumulation;

minimized by tunable couplers.

Stray Coupling (nearest-neighbor)

J_stray / 2pi

kHz

Unintended coupling between non-adjacent qubits; extracted from

full-chip EPR simulation.

< 10 kHz

< 50 kHz

50 – 200 kHz

> 500 kHz

Degrades multi-qubit gate fidelity; EPR full-chip simulation essential

to identify stray modes.