Controlled color light source

What is claimed is: 1. A light source, comprising: at least two semiconductor light-emitting elements, the semiconductor light-emitting elements emitting light of different color; a light guide into which the light is, at least partially, injected, the light guide being configured so that the light exits laterally from the light guide, the light guide having a longitudinal extension and an end face; a light sensor arranged to receive the light injected by the semiconductor light-emitting elements into the light guide and laterally exiting therefrom, wherein the light sensor is spaced along the longitudinal extension by a distance of between the light sensor and the end face; and an electronic control unit configured to accumulate sensor signals from the light sensor over an integration time interval of the brightness, determine a difference by comparing the accumulated signals with a target value or target range, change the brightness of the semiconductor light-emitting elements in response to the difference, and change the integration time interval in response to either the difference or a change in the target value or target range; wherein the electronic control unit is configured to respond to the change in the target value or target range by pre-adjusting the brightness based on stored values and by subsequently adjusting a color location based on the difference between the sensor signals and the target value or target range. 2. The light source as in claim 1 , further comprising a reflective element arranged to reflect part of the light laterally emitted from the guide light, wherein the light sensor is arranged to receive the light laterally emitted from the guide light and passing through the reflective element. 3. The light source as in claim 2 , wherein the reflective element is a reflective layer that extends around a portion of a circumference of the light guide. 4. The light source as in claim 3 , wherein the reflective element is a silicone coating with embedded light-scattering particles, the light-scattering particles having a refractive index of greater than two. 5. The light source as in claim 3 , wherein the reflective element passes less than 20% of light incident on the reflective element. 6. The light source as in claim 3 , wherein the reflective element is at least partially diffusely reflective so as to scatter the light conducted in the light guide in such a manner that the light scattered and thereby diffusely reflected exits laterally from the light guide. 7. The light source as in claim 1 , wherein the distance corresponds to at least twice a transverse dimension of the light guide. 8. The light source as in claim 1 , wherein the semiconductor light-emitting elements comprise a four-color LED array including at least one red emitting LED, at least one green or yellow emitting LED, at least one blue emitting LED, and at least one white light emitting LED. 9. The light source as in claim 1 , wherein the light sensor has a plurality of sensor areas with different dichroic filters and an aperture stop limiting an angular range of the light laterally emitted from the light guide and incident on the sensor areas to less than 90°. 10. The light source as in claim 1 , wherein the light guide has two end faces at opposite ends thereof, and wherein, for each end face of the two end faces, the at least two semiconductor light-emitting elements are arranged so that the light emitted therefrom is injected into the light guide through the respective end face. 11. The light source as in claim 10 , wherein the light sensor comprises a first light sensor and a second light sensor, wherein the first and second light sensors are is associated with a respective one of the two end faces so that the first and second light sensors receive a greater proportion of the light injected into the end face the light sensor is associated with, and wherein the electronic control unit is configured to control the two semiconductor light-emitting elements at each of the end faces independently from each other and on the basis of the sensor signals of the light sensor associated with the respective end face. 12. The light source as in claim 3 , wherein the semiconductor light-emitting elements have light-emitting areas with a center of gravity on the end face that is offset relative to a center of the end face in a direction away from the reflective layer. 13. The light source as in claim 1 , further comprising a light mixer and a light deflector, the two semiconductor light-emitting elements at least partially injecting light into the light mixer, wherein the light mixer has a longitudinal extension along which light is conducted that extends transversely to the longitudinal extension of the light guide, and wherein the light deflector is provided to redirect the light conducted in the light mixer towards an end face of the light guide so that after having been deflected the light is injected into the end face of the light guide. 14. The light source as in claim 13 , wherein the light mixer comprises a second light guide obliquely beveled with a bevel face and having a light entry area which is defined by a non-beveled end face of the second light guide, and a light exit area which is defined by a surface area of a wall at that end of the second light guide at which the bevel face is arranged, and a second optical element is provided which is defined by the light guide or by an optical element interposed between the light guide and the light mixer, wherein the second optical element has a light entry aperture arranged on the light exit area of the light mixer or facing the light exit area of the first optical element, wherein the light entry area of the second light guide has a width x measured in the direction along the intersection of the light entry area with the plane of light deflection at the bevel face, and the light entry aperture of the second optical element has a height z measured in the direction along the intersection of the light exit area of the second light guide with the plane of light deflection at the bevel face, which meet the following relationship: x/z ≤1.5·[tan(90°−α/2)−tan(90°−(2·[α/2+90°]−[180°−arcsin(1 /n )]))] −1 , wherein α denotes the deflection angle of the light at the bevel face, and n denotes the refractive index of the material of the second light guide. 15. The light source as in claim 14 , wherein the height z of the light entry aperture and the width x meet the following relationship: x/z ≤1.5·[1+tan(arcsin(1/ n ))] −1 , wherein n denotes the refractive index of the material of the second light guide. 16. The light source as in claim 13 , wherein the light mixer is a prism-shaped light guide obliquely beveled with a bevel face that defines a reflective face, wherein the light mixer has a cross-sectional area with a shape having dimensions monotonically expanding in a direction from the surface facing away from the light guide towards the light guide, and strictly monotonically expanding in at least one section along this direction. 17. A lighting device, comprising: a plurality of the light sources claimed in claim 1 ; a control device; and a data line, wherein the control device is configured to output data that represents color values, wherein the electronic control units of the light sources are connected to the control device via the data line, and wherein the electronic control units are adapted to store the color values received via the data line as the target values or target ranges and to change the brightness based o