A light emitting device is disclosed that emits light from the surface in
a broad spectral range and in a broad range of angles tilted with respect
to the direction normal to the exit surface. An apparatus for generating
wavelength-stabilized light is formed of a light-emitting device, an
external cavity and at least one external mirror. Light emitted by the
light-emitting device at a certain preselected angle, propagates through
the external cavity, impinges on the external mirror and is reflected
back. Light emitted at other angles does not impinge on the external
mirror. Thus, a feedback occurs only for the light emitted at a
preselected angle. Light impinged on the external mirror and reflected
back undergoes interference with the emitted light. The interference can
be constructive or destructive. Constructive interference results in a
positive feedback. The positive feedback occurs, if light emitted by the
light-emitting device is reflected back and reaches the active region in
phase, i.e. if the phase matching between emitted and reflected light
waves occurs. The positive feedback conditions are met at one or a few
selected wavelengths within the luminescence spectrum of the active
region. Then the apparatus generates wavelength-stabilized light. In
different embodiments, an apparatus may operate as a
wavelength-stabilized light-emitting diode, a wavelength-stabilized
superluminescent light-emitting diode, or a wavelength-stabilized
laser.Various embodiments are possible which are distinguished in a way
of optical coupling between a light-emitting device and an external
mirror. The coupling can be realized via the far-field zone of the light
emitted by the light-emitting device, via the near-field zone, or via a
single epitaxial structure.An apparatus for the frequency conversion is
disclosed further comprising a non-linear crystal located within the
external cavity.