초록 ▼

Apparatus to provide a time reference are disclosed herein. An example apparatus disclosed herein includes a resonator. A first cap is coupled to a first side of the resonator to define a first cavity, and a second cap is coupled to a second side of the resonator to define a second cavity. The first

Apparatus to provide a time reference are disclosed herein. An example apparatus disclosed herein includes a resonator. A first cap is coupled to a first side of the resonator to define a first cavity, and a second cap is coupled to a second side of the resonator to define a second cavity. The first cavity and the second cavity provide a first vacuum in which the resonator is to resonate. The resonator, the first cap and the second cap have substantially identical thermal expansion coefficients. The example apparatus also includes a vacuum chamber surrounding the resonator, the first cap and the second cap. The vacuum chamber is to provide a second vacuum in which the resonator, the first cap and the second cap are disposed. A frequency of resonance of the resonator in the first vacuum is to provide a time reference.

대표청구항 ▼

1. An apparatus, comprising: a resonator;a first cap coupled to a first side of the resonator to define a first cavity;a second cap coupled to a second side of the resonator to define a second cavity, the resonator, the first cap and the second cap having substantially identical thermal expansion co

1. An apparatus, comprising: a resonator;a first cap coupled to a first side of the resonator to define a first cavity;a second cap coupled to a second side of the resonator to define a second cavity, the resonator, the first cap and the second cap having substantially identical thermal expansion coefficients, wherein the first cavity and the second cavity provide a first vacuum in which the resonator is to resonate;a vacuum chamber surrounding the resonator, the first cap and the second cap, the vacuum chamber to provide a second vacuum in which the resonator, the first cap and the second cap are disposed, wherein the resonator is a dual-mode resonator, wherein a frequency of resonance of the resonator in the first vacuum and the second vacuum is to provide a time reference for dynamic calibration using an analytical thermal stress model, wherein the first cap, the second cap and the resonator have substantially identical crystal orientations;anda first electrode and a second electrode, a first portion of the first electrode substantially ring-shaped and disposed on a first circumferential surface of the first cap, a second portion of the second electrode substantially ring-shaped and disposed on a second circumferential surface of the second cap, wherein the first electrode and the second electrode are cylindrically shaped and symmetric relative to a longitudinal axis of the apparatus for enabling heat propagation paths through the first electrode and the second electrode. 2. The apparatus of claim 1 further comprising a thermally insulating support, wherein the first cap, the second cap and the resonator are coupled to the vacuum chamber via the support. 3. The apparatus of claim 1 wherein the first cap, the second cap and the resonator are composed of quartz. 4. The apparatus of claim 1 wherein the first cap and the second cap have substantially identical shapes. 5. An apparatus, comprising: a clock including a first crystal cap, a second crystal cap and a crystal resonator, a portion of the crystal resonator disposed in a first vacuum between the first crystal cap and the second crystal cap, wherein the crystal resonator is a dual-mode resonator, wherein the crystal resonator, the first crystal cap and the second crystal cap have substantially identical crystal orientations and coefficients of thermal expansion;a vacuum chamber, the clock disposed inside the vacuum chamber in a second vacuum to provide a time reference for dynamic calibration using an analytical thermal stress model;anda first electrode and a second electrode, a first portion of the first electrode substantially ring-shaped and disposed on a first circumferential surface of the first cap, a second portion of the second electrode substantially ring-shaped and disposed on a second circumferential surface of the second cap, wherein the first electrode and the second electrode are cylindrically shaped and symmetric relative to a longitudinal axis of the clock for enabling heat propagation paths through the first electrode and the second electrode. 6. The apparatus of claim 5 further comprising a thermal insulating support, wherein the first crystal cap, the second crystal cap and the crystal resonator are coupled to the vacuum chamber via the support. 7. The apparatus of claim 5 wherein the first crystal cap, the second crystal cap and the crystal resonator are composed of quartz. 8. The apparatus of claim 5 wherein the first crystal cap is substantially symmetric relative to the second crystal cap. 9. An apparatus, comprising: a clock to be disposed in a first vacuum of a vacuum chamber, the clock comprising a first quartz layer, a second quartz layer and a third quartz layer, wherein the second quartz layer is a dual-mode resonator, wherein a portion of the second quartz layer is disposed in a second vacuum between the first quartz layer and the third quartz layer, wherein a frequency of resonance of the second quartz layer is to provide a time reference for dynamic calibration using an analytical thermal stress model, and wherein the first quartz layer, the second quartz layer and the third quartz layer have substantially identical crystal orientations; anda first electrode and a second electrode, a first portion of the first electrode substantially ring-shaped and disposed on a first circumferential surface of the first quartz layer, a second portion of the second electrode substantially ring-shaped and disposed on a second circumferential surface of the second quartz layer, wherein the first electrode and the second electrode are cylindrically shaped and symmetric relative to a longitudinal axis of the clock for enabling heat propagation paths through the first electrode and the second electrode.