Stability Diagram and Stability Criterions As described in textbooks for instance LASERS of A. E. Siegman, the stability diagram initially has been de-

Slides:

Advertisements

Similar presentations

Notation for Mirrors and Lenses

Advertisements

Modern Optics Lab Experiment 2: REFLECTION AND REFRACTION AT SPHERICAL INTERFACES  Measuring: Radii of mirrors and lenses Focal points of mirrors, spherical.

Laser Physics EAL 501 Lecture 6 Power & Frequency.

Chapter 2 Propagation of Laser Beams

Nonlinear Optics Lab. Hanyang Univ. Chapter 2. The Propagation of Rays and Beams 2.0 Introduction Propagation of Ray through optical element : Ray (transfer)

Fundamental of Optical Engineering Lecture 4.  Recall for the four Maxwell’s equation:

Gaussian Beam Propagation Code

Chapter 23 Mirrors and Lenses.

1 Introduction to Optical Electronics Quantum (Photon) Optics (Ch 12) Resonators (Ch 10) Electromagnetic Optics (Ch 5) Wave Optics (Ch 2 & 3) Ray Optics.

Chapter 23 Mirrors and Lenses. Notation for Mirrors and Lenses The object distance is the distance from the object to the mirror or lens Denoted by p.

COMPUTER MODELING OF LASER SYSTEMS

Lecture 23 Mirrors Lens.

Curved Mirrors SNC2P – Optics. Curved Mirrors Curved mirrors are created when you make part of the surface of a sphere reflective There are two types.

Higher order TEM modes: Why and How? Andreas Freise European Gravitational Observatory 17. March 2004.

1 Adjoint Method in Network Analysis Dr. Janusz A. Starzyk.

Physics 1502: Lecture 29 Today’s Agenda Announcements: –Midterm 2: Monday Nov. 16 … –Homework 08: due Friday Optics –Index of Refraction.

The Ray Vector A light ray can be defined by two co-ordinates: x in,  in x out,  out its position, x its slope,  Optical axis optical ray x  These.

Thin Lenses If the thickness of the lens is small compared to the object and image distances we can neglect the thickness (t) of the lens. All thin lenses.

Imaging Science FundamentalsChester F. Carlson Center for Imaging Science Mirrors and Lenses.

Module 1-4 Basic Geometrical Optics. Image Formation with Lenses Lenses are at the heart of many optical devices, not the least of which are cameras,

Computational Physics Approaches to Model Solid-State Laser Resonators Konrad Altmann LAS-CAD GmbH, Germany LASer Cavity Analysis & Design.

1© Manhattan Press (H.K.) Ltd. Terms used for lenses Images in lenses Images in lenses 12.2 Converging and diverging lenses Lens formula Lens formula.

The FEA Code of LASCAD Heat removal and thermal lensing constitute key problems for the design of laser cavities for solid-state lasers (SSL, DPSSL etc.).

Magnifications in Mirrors & Lenses.  A measure of how much larger or smaller an image is compared with the object itself. Magnification = image height.

Chapter 23 Mirrors and Lenses.

Optics and Light Lenses form images by refracting light.

Geometric Optics This chapter covers how images form when light bounces off mirrors and refracts through lenses. There are two different kinds of images:

Engineering Optics Understanding light? Reflection and refraction Geometric optics (

Interaction of radiation with atoms and ions (I) Absorption- Stimulated emission E1E1 E2E2 W 12 =W 21 Spontaneous emission More definitionsCross section.

Chapter 36 Image Formation.

1 MODELING MATTER AT NANOSCALES 4. Introduction to quantum treatments The variational method.

Lecture 24 Interference of Light.

ECEN 4616/5616 Optoelectronic Design Class website with past lectures, various files, and assignments: (The.

Rays and imaging v_optics/examples/optics_bench.html.

Nonlinear Optics Lab. Hanyang Univ. Chapter 6. Processes Resulting from the Intensity-Dependent Refractive Index - Optical phase conjugation - Self-focusing.

The law of reflection: The law of refraction: Image formation

Zeuten 19 - E. Wilson - 1/18/ Slide 1 Recap. of Transverse Dynamics E. Wilson – 15 th September 2003  Transverse Coordinates  Relativistic definitions.

Chapter 18 Mirrors and Lenses. Objectives 18.1 Explain how concave, convex, and plane mirrors form images 18.1 Locate images using ray diagrams, and calculate.

EKT 441 MICROWAVE COMMUNICATIONS CHAPTER 3: MICROWAVE NETWORK ANALYSIS (PART 1)

Space-time analogy True for all pulse/beam shapes

PHYS 408 Applied Optics (Lecture 11) JAN-APRIL 2016 EDITION JEFF YOUNG AMPEL RM 113.

Principal planes method For the purposes of finding images, we can reduce any* optical system to a thin lens. Principal plane distances p 1 and p 2 are.

PHYS 408 Applied Optics (Lecture 12) JAN-APRIL 2016 EDITION JEFF YOUNG AMPEL RM 113.

PHYS 408 Applied Optics (Lecture 16) JAN-APRIL 2016 EDITION JEFF YOUNG AMPEL RM 113.

§3.3 Optical Resonators with Spherical Mirrors We will show the field solutions inside the spherical mirror resonator are Gaussian Beams Z=0 00 z R2R2.

Chapter 1. Ray Optics.

Image Formation. The light rays coming from the leaves in the background of this scene did not form a focused image on the film of the camera that took.

Part 10 Optics --Mirrors and Lenses Chapter 24 Geometric Optics.

講者：許永昌老師 1. Contents The Ray Model of Light Object Eye Ray diagram and Ray tracing Aperture Reflection Specular reflection The Plane Mirror Diffuse.

LASCAD  - The Laser Engineering Tool The results of FEA can be used with the ABCD gaussian propagation as well as with the BPM physical optics code. FEA.

Geometric Optics Figure Mirrors with convex and concave spherical surfaces. Note that θr = θi for each ray.

Dynamic Analysis of Multimode and Q-Switch Operation (DMA)

PHYS 408 Applied Optics (Lecture 15)

Digital and Non-Linear Control

PHYS 408 Applied Optics (Lecture 16)

Optics – The Behaviour of Light

EKT 356 MICROWAVE COMMUNICATIONS

Physics 7E Prof. D. Casper.

Chapter III Optical Resonators

Chapter 3 Polarization of Light Waves

Interaction of radiation with atoms and ions (I)

Thin lenses Lec. three.

PHYS 408 Applied Optics (Lecture 15)

Thin-disk laser multi-pass amplifier

PHYS 408 Applied Optics (Lecture 14)

PHYS 408 Applied Optics (Lecture 14)

Chapter II The Propagation of Rays and Beams

Scalar theory of diffraction

Imaging ABCD matrix can represent an imaging system, including object distance do and image distance di optics ABCDtotal condition for imaging! _____.

Chapter 6. STABILITY Good relationships nurture you. They help you find yourself and who you are. I don’t mean just relationships with boys or men. Relationships.

Presentation transcript:

Stability Diagram and Stability Criterions As described in textbooks for instance LASERS of A. E. Siegman, the stability diagram initially has been de- veloped for the standing wave two-mirror resonator. For this resonator real and finite solutions of the gaussian beam parameters and spot sizes only exist, if the following criterion is met with and Here L is the distance of the mirrors and R 1 and R 2 are the radii of curvature of left and right mirror, respectively.

Stability diagram

As shown in PRINCIPLES OF LASERS, Sect. 5.5 by O. Svelto this concept can be generalized to the case of the general standing wave resonator with internal optical elements by introduction of the single-pass ABCD matrix.

R=∞ For this purpose we replace the curved mirrors by plane mirrors combined with appropriate thin lenses The elements between the plane mirrors now can be described by a single-pass ABCD matrix.

A 1 B 1 C 1 D 1 R=∞ In case of an empty two-mirror resonator it can be shown that For the general single-pass matrix representing a series of arbitrary internal elements these relations can be generalized to

The generalized parameters g* 1 and g* 2 must meet the same stability criterions as g 1 and g 2 To derive this relation the full round-trip matrix has to be computed Building the half-trace of the matrix at the right hand side we obtain

Since the half-trace of the full round-trip matrix must mett the stability criterion it follows or Therefore, by the use of the generalized g-parameters a stability diagram can be shown for any standing wave resonator for instance with internal thermal lens.

Strictly speaking, the concept of the single-pass matrix only is valid if gain guiding can be neglected. However, since in most real cases the influence gain guiding is week, the generalized stability diagram is a useful tool to analyze to analyze cavity stability. However, this concept cannot be used for ring cavities, since in this case the single-path matrix is identical to the full round-trip matrix. In this case the half-trace of the full round-trip matrix must be used as a reference value. Alternatively, the concept of perturbation eigenvalues as introduced in the book LASERS of Siegman can be used