Optical: systems and elements – Optical amplifier – Particular resonator cavity
Reexamination Certificate
1999-01-13
2001-03-13
Hellner, Mark (Department: 3662)
Optical: systems and elements
Optical amplifier
Particular resonator cavity
C372S022000
Reexamination Certificate
active
06201638
ABSTRACT:
BACKGROUND OF THE INVENTION
1. Field of the Invention
This invention relates to the field of optical frequency generators, and more specifically, to the generation of optical frequency combs.
2. Description of the Related Art
An Electro-Optic Modulator (EOM), when driven by an appropriate single Radio Frequency (RF) electromagnetic field, produces optical frequency light sidebands on an original single frequency light beam that traverses the EOM. The sidebands are equally spaced about the input beam. The spectral extent of the sidebands can be increased by recirculating the modulated light beam through the EOM, to thereby iteratively produce additional light sidebands on each daughter light beam that was generated by a previous interaction. In this way, an optical comb is built up, the spectral extension of which is limited by optical transmission losses, phase mismatching error associated with synchronization or length errors, and wavelength “breadth” induced phase dispersion of the EOM and its mirrors. (See, for example, “A Highly Accurate Frequency Counting System for 1.5 Micro Meter Wavelength Semiconductor Lasers’, PROCEEDINGS OF THE SPIE, Vol. 1837, 16-18 Nov. 1992, pp. 205-215, by M. Kurogi, K. Nakagawa, and M. Ohtsu, and “Optical Frequency Comb Generator”,
IEEE J. Quant. Electr
., Vol. 29, Oct. 1993 pp. 2693-2701 (1993), by M. Kurogi, K. Nakagawa, and M. Ohtsu.
FIG. 1
shows the output of such a prior comb generating cavity
60
that operates to generate an optical frequency comb
61
having sideband portions
62
and
63
that are centered upon the frequency
64
of an input laser
65
. Increasing frequencies within OFC
61
are shown by increasing values along the X axis, and the relative power in each comb frequency is shown on the logarithmic Y axis, the power of frequency
64
being the largest amplitude
In accordance with an aspect of the present invention, comb-generating cavity
60
includes an optical amplifier or optical parametric amplifier, and the utility of optical comb
61
is enhanced by the use of a resonant and tunable bandpass filter optical cavity that operates as a direct output coupler for comb-generating cavity
60
. This output coupler operates to increase the strength of a selected comb frequency component by several orders of magnitude.
A publication by John. L. Hall (“Frequency stabilized lasers—a parochial review”,
Proceedings Reprint, SPIE
, Vol. 1837, 16-18 November 1992, pgs. 2-15, at section 5.4.2 on page 12) recognizes Kurogi, Nakagawa and Ohtsu as providing a microwave modulator that is enclosed in a low-loss cavity, wherein a sideband that is produced on the first transit is used as the source for a second sideband, and the second for a third, etc., whereby a spectral width of about + and −4 THz is provided, made up of individual lines spaced by the 5.6 GHz frequency. Hall then suggests “recycling” the light reflected back toward the source from the entrance mirror. It is also suggested that if this recycling cavity is short enough, the recycling cavity could be resonance free until one reaches the desired high order sideband, perhaps some THz away. The modulation power in this line would be coupled back toward the source, and could be separated with a Faraday isolator system. It is suggested that such schemes may make it feasible to transfer the stability of one optical source in a phase coherent manner to another source located an appreciable frequency interval away.
An article entitled “A Coupled Cavity Monolithic Optical Frequency Comb Generator” by M. Kourogi, T. Enaeni and M . Ohtsu in IEEE PHOTONICS TECHNOLOGY LETTERS, Vol. 8, No. 12, December 1996, describes an optical frequency comb generator (or a Fabry Perot electro-optic modulator) that generates ultra short optical pulses, and high order sidebands from a single mode laser input. A high efficiency electro-optic phase modulator is installed in a high finesse optical cavity, and driven with an integer multiple of the cavity free spectral range.
Two types of optical frequency comb generators are discussed, each having an external coupled cavity, one to achieve efficient comb generation, and the other to provide a frequency shifter.
In the
FIG. 1
a
embodiment of this publication, a mirror M
3
was mounted on a PZT transducer, and placed in front of a mirror M
1
to form a coupled cavity, and the coupled cavity was adjusted to the laser frequency. As a result, the incident light is transmitted by the coupled cavity, while the coupled cavity becomes highly reflective for the sidebands generated by the comb generator.
To allow the selection of extracted sidebands, the above-described coupled cavity of
FIG. 1
a
was removed from the input port of the comb generator, and as shown in
FIG. 1
b
of this publication, and PZT mounted mirror M
3
was installed at the output port. By adjusting the bias voltage at the PZT on which mirror M
3
was mounted, an appropriate set of sidebands may be selected.
This publication also suggests that if two stable coupled cavities are installed at the input and the output port of the comb generator, the power of the selected sideband may be increased, in which case, the comb generator will become a highly efficiency frequency shifter for a wide frequency range.
An article entitled “Efficient optical frequency comb generator” by A. S. Bell, G. M. McFarlane, E. Riis and A. I. Ferguson, OPTICS LETTERS, Vol. 20. No. 12, Jun. 15, 1995, also describes an arrangement having two cavities that are locked to a laser carrier frequency. This publication describes how an unknown laser frequency can be measured with respect to a well-known standard frequency. This publication also describes how large frequency differences can be determined, based on a few rf measurements. A comb of equally-spaced modes is produced from a single laser carrier frequency. An electro-optic modulator superimposes a microwave frequency onto the carrier frequency, thus producing a comb of nodes with spacing of exactly the microwave frequency. The electro-optic modulator is placed into a three mirror dogleg cavity that is resonant to both the carrier frequency and the sidebands. A second cavity is used to ensure that most of the incident laser power is coupled into the optical cavity. To increase the coupling of the laser into the optical cavity, and hence increase the throughput of the comb generator, a PZT-mounted mirror M
1
is placed before the mirror M
2
of the optical cavity that contains the electro-optic modulator to thus form a coupling cavity. The coupling cavity was then frequency locked to the input light.
SUMMARY OF THE INVENTION
In an implementation of the present invention, an Electro-Optic Modulator (EOM) crystal is placed inside of a low loss, two mirror, comb-generating optical cavity that is in resonance with an input laser carrier frequency, and with all carrier sidebands frequencies. That is, the laser carrier frequency equals an integral multiple of the comb-generating optical cavity's
Free Spectral Range (FSR). Equally important, the radio frequency that is applied to the modulator also is a multiple of the cavity's FSR.
More specifically, an Optical Frequency Comb (OFC) with a span that is wider than 3 THz is provided by a 10.5 GHz resonant EOM modulator that is placed inside of a resonant comb-generating optical cavity that includes two physically spaced mirrors, and whose cavity input is a reference beam produced by a He—Ne laser that operates at about 633 nanometers (i.e., red). A low noise RF microwave oscillator drives the EOM at 10.5-GHz, so that high order sidebands do not quickly collapse due to multiplied phase noise amplitude.
A two mirror, thin, bandpass filter optical cavity, having a free spectral range of 2-THz and a finesse of 400, functions as a direct output coupler for the comb-generating cavity. The bandpass filter cavity and the comb-generating cavity share a common fixed position mirror. This bandpass filter cavity is tuned into resonance with the selected sideband of the 633-nanometer laser, thus providing efficient
Diddams Scott Alan
Hall John Lewis
Ma Long-Sheng
Ye Jun
Hancock E. C.
Hellner Mark
Holland & Hart LLP
Sirr F. A.
University Technology Corporation
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