Radiation receiver apparatus

The invention claimed is: 1. Radiation receiver apparatus with a radiation receiver and with a radiation entrance face, wherein the radiation receiver comprises an active region that detects radiation with a target wavelength in the near-infrared; an optical element is arranged between the radiation entrance face and the radiation receiver; an optical axis of the optical element extends through the radiation receiver; the optical element is shaped and arranged relative to the radiation receiver such that, of radiation incident on the radiation entrance face at an angle of greater than or equal to 40° to the optical axis, at most 10% is incident on the radiation receiver; a visible light filter is formed between the radiation receiver and the radiation entrance face; and the radiation receiver apparatus further comprises a semiconductor filter in addition to the visible light filter, the semiconductor filter being arranged between the radiation receiver and the radiation entrance face to suppress radiation of a wavelength smaller than a cut-off wavelength, wherein the cut-off wavelength is smaller than the target wavelength. 2. The radiation receiver apparatus according to claim 1 , wherein, at an angle of 15° to 25° to the optical axis an angle-dependent sensitivity distribution of the radiation receiver apparatus decreases to half the value at an angle of 0°. 3. The radiation receiver apparatus according to claim 1 , wherein the radiation receiver is embedded in an enclosure and the visible light filter is formed by a filler in the enclosure. 4. The radiation receiver apparatus according to claim 1 , wherein an interfering radiation filter is arranged between the radiation receiver and the optical element to suppress interfering radiation in the near-infrared or the visible spectral range with modulation frequencies in the kHz range. 5. The radiation receiver apparatus according to claim 4 , wherein the interfering radiation filter suppresses interfering radiation with an interfering wavelength relative to the target wavelength of the radiation receiver with a contrast ratio of at least 1:50. 6. The radiation receiver apparatus according to claim 5 , wherein the interfering wavelength is larger than the target wavelength. 7. The radiation receiver apparatus according to claim 5 , wherein the interfering wavelength is 1014 nm and the target wavelength is 920 nm to 960 nm. 8. The radiation receiver apparatus according to claim 1 , wherein a semiconductor filter is arranged between the radiation receiver and the radiation entrance face to suppress radiation of a wavelength smaller than a cut-off wavelength, and the cut-off wavelength is smaller than the target wavelength. 9. The radiation receiver apparatus according to claim 1 , wherein the radiation receiver comprises a plurality of active regions arranged along the optical axis. 10. The radiation receiver apparatus according to claim 9 , wherein the signals generated in the active regions when the radiation receiver apparatus is in operation may be individually tapped at the radiation receiver. 11. The radiation receiver apparatus according to claim 1 , wherein the radiation receiver apparatus comprises an electrical bandwidth of 20 kHz to 800 kHz. 12. The radiation receiver apparatus according to claim 1 , wherein the radiation receiver apparatus is configured as a surface-mountable device. 13. The radiation receiver apparatus according to claim 12 , wherein a mounting surface of the surface-mountable device extends parallel to the optical axis. 14. The radiation receiver apparatus according to claim 1 , wherein the optical element comprises a lens and an angle-dependent sensitivity distribution of the radiation receiver apparatus decreases from a maximum value at an angle of 0° to the optical axis to at most 10% of the maximum value at an angle of at most 40°. 15. The radiation receiver apparatus of claim 1 , wherein the semiconductor filter contains an arsenide compound semiconductor material with an aluminum content greater than an aluminum content of the active region. 16. Radiation receiver apparatus with a radiation receiver and a radiation entrance face, wherein the radiation receiver comprises an active region that detects radiation with a target wavelength in the near-infrared; an optical element is arranged between the radiation entrance face and the radiation receiver; an optical axis of the optical element extends through the radiation receiver; the optical element is shaped and arranged relative to the radiation receiver such that, of radiation incident on the radiation entrance face at an angle of greater than or equal to 40° to the optical axis, at most 10% is incident on the radiation receiver; a visible light filter is formed between the radiation receiver and the radiation entrance face; and the radiation receiver is embedded in an enclosure and the visible light filter is formed by a filler in the enclosure. 17. Radiation receiver apparatus with a radiation receiver and a radiation entrance face, wherein the radiation receiver comprises an active region that detects radiation with a target wavelength in the near-infrared; an optical element is arranged between the radiation entrance face and the radiation receiver; an optical axis of the optical element extends through the radiation receiver; the optical element is shaped and arranged relative to the radiation receiver such that, of radiation incident on the radiation entrance face at an angle of greater than or equal to 40° to the optical axis, at most 10% is incident on the radiation receiver; a visible light filter is formed between the radiation receiver and the radiation entrance face; the radiation receiver comprises a plurality of active regions arranged along the optical axis; and the signals generated in the active regions when the radiation receiver apparatus is in operation may be individually tapped at the radiation receiver.