Broadband resonator optical gyroscope with efficient optical power management for low shot noise

What is claimed is: 1. A resonator optical gyroscope, comprising: a broadband light source configured to generate optical signals having a broadband frequency range; an optical resonator; a first optical coupler coupled to the optical resonator, wherein the first optical coupler is configured to receive the optical signals from the broadband light source and couple the optical signals into the optical resonator such that the optical signals propagate in a first direction through the optical resonator, wherein the first optical coupler is also configured to couple amplified optical signals out of the optical resonator after the amplified optical signals pass through the optical resonator in a second direction; a second optical coupler coupled to the optical resonator, wherein the second optical coupler is configured to couple the optical signals out of the optical resonator after the optical signals pass through the optical resonator in the first direction, wherein the second optical coupler is also configured to couple the amplified optical signals into the optical resonator such that the optical signals propagate in the second direction through the optical resonator; a gain element configured to receive the optical signals coupled out of the optical resonator by the second optical coupler and to amplify the optical signals that have been coupled out of the optical resonator by the second optical coupler and passed through the optical resonator in the first direction to generate the amplified optical signals; a photodetector configured to convert the amplified optical signals to corresponding electrical signals based on a power level of the amplified optical signals; and one or more circuits configured to determine a rate of rotation based on the corresponding electrical signals. 2. The resonator optical gyroscope of claim 1 , further comprising a first pump laser configured to optically pump the gain element and the broadband light source. 3. The resonator optical gyroscope of claim 1 , further comprising: at least one power monitor configured to measure the power level of the amplified optical signals; and at least one control circuit configured to adjust the gain element based on the measured power level of the optical signals. 4. The resonator optical gyroscope of claim 1 , further comprising: a first circulator coupled between the broadband light source and the first optical coupler, wherein the first circulator is configured to provide the optical signals from the broadband light source to the first optical coupler and to provide the amplified optical signals from the first optical coupler to the photodetector; and/or a second circulator coupled to the second optical coupler, wherein the second circulator is configured to provide the optical signals from the second optical coupler to the gain element. 5. The resonator optical gyroscope of claim 1 , further comprising a fiber reflector or waveguide reflector configured to back reflect the optical signals toward the gain element or a phase modulator. 6. The resonator optical gyroscope of claim 1 , further comprising a phase modulator configured to apply a phase modulation to the amplified optical signals. 7. A resonator optical gyroscope, comprising: a broadband light source configured to generate optical signals having a broadband frequency range; an optical resonator; a first optical coupler coupled to the optical resonator, wherein the first optical coupler is configured to receive the optical signals from the broadband light source and couple the optical signals into the optical resonator such that the optical signals propagate in a first direction through the optical resonator, wherein the first optical coupler is also configured to couple the optical signals out of the optical resonator after the optical signals pass through the optical resonator in a second direction; a second optical coupler coupled to the optical resonator, wherein the second optical coupler is configured to couple the optical signals out of the optical resonator after the optical signals pass through the optical resonator in the first direction, wherein the second optical coupler is also configured to couple the optical signals into the optical resonator such that the optical signals propagate in the second direction through the optical resonator; one or more gain elements configured to amplify the optical signals that have been coupled out of the optical resonator by the second optical coupler and passed through the optical resonator in the first direction and/or the optical signals that have been coupled out of the optical resonator by the first optical coupler and passed through the optical resonator in the second direction; a photodetector configured to convert amplified optical signals to corresponding electrical signals based on a power level of the amplified optical signals; one or more circuits configured to determine a rate of rotation based on the corresponding electrical signals; a phase modulator; and either: (a) wherein the one or more gain elements include a first gain element configured to receive the optical signals coupled out of the optical resonator by the second optical coupler and to amplify the optical signals coupled out of the optical resonator by the second optical coupler to generate the amplified optical signals; wherein the phase modulator is configured to receive the amplified optical signals from the first gain element and apply a phase modulation to the amplified optical signals to generate phase-modulated, amplified optical signals; wherein the second optical coupler is configured to couple the phase-modulated, amplified optical signals into the optical resonator such that the phase-modulated, amplified optical signals propagate in the second direction through the optical resonator; wherein the first optical coupler is configured to couple the phase-modulated, amplified optical signals out of the optical resonator after the phase-modulated, amplified optical signals pass through the optical resonator in the second direction; (b) wherein the phase modulator is configured to receive the optical signals coupled out of the optical resonator by the second optical coupler and apply the phase modulation to the optical signals to generate phase-modulated optical signals; wherein the second optical coupler is configured to couple the phase-modulated optical signals into the optical resonator such that the phase-modulated optical signals propagate in the second direction through the optical resonator; wherein the first optical coupler is configured to couple the phase-modulated optical signals out of the optical resonator after the phase-modulated optical signals pass through the optical resonator in the second direction; wherein the one or more gain elements include the first gain element configured to receive the phase-modulated optical signals coupled out of the optical resonator by the first optical coupler and to amplify the phase-modulated optical signals to generate the phase-modulated, amplified optical signals; or (c) wherein the phase modulator is configured to receive the optical signals coupled out of the optical resonator by the second optical coupler and apply the phase modulation to the optical signals to generate the phase-modulated optical signals; wherein the one or more gain elements include a first gain element configured to receive the phase-modulated optical signals from the phase modulator and to amplify the phase-modulated optical signals to generate the phase-modulated, amplified optical signals; wherein the second optical coupler is configured to couple the phase-modulated, amplified optical signals into the optical resonator such that the phase-modulated, amplified optic