Claims
- 1. A multiple pump solid state tunable laser comprising:
- an output coupler for transmitting an output laser beam;
- a broadband tuning mechanism including at least one isosceles prism; and
- a dispersion compensation apparatus located between said output coupler and said broadband tuning mechanism including opposite chirality optical lasing elements each having a Brewster angle face for separately receiving a pump beam without interfering with the output laser beam.
- 2. The multiple pump solid state tunable laser of claim 1 in which said isosceles prism includes a near Brewster angle face for receiving a seed input supplied to one of said optical lasing elements.
- 3. The multiple pump solid state tunable laser of claim 1 in which said opposite chirality optical lasing elements are titanium sapphire.
- 4. The multiple pump solid state tunable laser of claim 1 in which said output coupler includes a graded reflectivity mirror for eliminating diffraction.
- 5. The multiple pump solid state tunable laser of claim 1 in which said broadband tuning mechanism further includes a high reflectivity mirror and a plurality of isosceles prisms arranged in series between said dispersion compensation apparatus and high reflectivity mirror.
- 6. The multiple pump solid state tunable laser of claim 5 in which each said isosceles prism is an isosceles Brewster prism orientated at a minimum deviation angle for spatially dispersing the laser beam into a plurality of wavelengths.
- 7. The multiple pump solid state tunable laser of claim 6 in which said high reflectivity mirror is adjustable for discretely selecting one said wavelength.
- 8. A solid state injection seeded laser comprising:
- an output coupler for transmitting an output laser beam;
- a seed port including a reflective surface at an acute non-Brewster angle; and
- a dispersion compensation apparatus located between said output coupler and said seed port including opposite chirality optical elements for fixing in space the output laser beam through a broadband tuning range.
- 9. The solid state injection seeded laser of claim 8 in which each said opposite chirality optical element includes a Brewster angle face for separately receiving a pump beam without interfering with the output laser beam.
- 10. The solid state injection seeded laser of claim 8 in which said opposite chirality optical elements are a titanium sapphire lasing medium.
- 11. The solid state injection seeded laser of claim 8 in which said opposite chirality optical elements include plane parallel windows and the laser further includes a lasing medium disposed between said plane parallel windows.
- 12. The solid state injection seeded laser of claim 8 in which said opposite chirality elements include a series of refractive prisms and the laser further includes a lasing medium disposed midway in the series of said refractive prisms.
- 13. A multiple pump solid state laser comprising:
- a pair of opposite chirality optical lasing elements each including end faces cut at the Brewster angle for receiving two pump beams without interfering with an output laser beam and for maximizing the total pumping power with decreased pump input on each said element thereby reducing possibility of damaging said end faces, each said element further including a Brewster angle face facing the other said element for dispersion compensation; and
- an output coupler for transmitting the output laser beam from said lasing elements and eliminating diffraction.
- 14. The multiple pump solid state laser of claim 13 further including a seed input pot including an isosceles prism having a near Brewster angle face for transmitting a seed input to one said end face of said pair of opposite chirality optical lasing elements.
Parent Case Info
This is a continuation of application Ser. No. 07/649,413, filed Feb. 1, 1991 now abandoned.
Government Interests
This invention was made with government support under contract NAS 1-18457 awarded by NASA. The government has certain rights in this invention.
US Referenced Citations (10)
Non-Patent Literature Citations (2)
Entry |
Shand et al; ("Tunable Solid State Lasers"); Proc of the OSA Topical Meet. on Tunable Solid State Lasers May 1-3, 1989. |
Spence et al; "60-sec Pulse Generation for a Self-Mode-Locked Ti: Sapphire Laser"; Opt. Lett. vol. 16, No. 1, Jan. 1, 1991. |
Continuations (1)
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Number |
Date |
Country |
Parent |
649413 |
Feb 1991 |
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