Monitoring of vital body signals during movement

The invention claimed is: 1. A method of monitoring respiration signals on a body of a human or animal, the method comprising: placing at least two tri-axial acceleration sensors on a sternum of said body with the at least two acceleration sensors separated by the point that separates the main body of the sternum and a manubrium in such a way that an angle change induced by said respiration signals differs between said at least two acceleration sensors, using said at least two acceleration sensors to measure respective acceleration vectors; and retrieving said respiration signals by applying differential angle measurement to the acceleration vectors measured by said at least two acceleration sensors to extract said respiration signals. 2. The method according to claim 1 , wherein said retrieving comprises applying said differential angle measurement by measuring an angle difference between acceleration vectors of said at least two acceleration sensors. 3. The method according to claim 2 , wherein said placing comprises aligning said at least two acceleration sensors in such a way that their measurement axes are substantially in the same spatial plane. 4. The method according to claim 1 , further comprising using said at least two acceleration sensors in respiration sensing as inclinometers to reflect chest movement caused by respiration. 5. The method according to claim 1 , further comprising using said at least two acceleration sensors in pulse sensing to catch mechanical vibration caused by heart pumping. 6. A method of monitoring respiration signals on a body of a human, the method comprising: placing two tri-axial acceleration sensors on top of a sternum of said body with the two acceleration sensors separated by the point that separates the main body of the sternum and a manubrium; using said two acceleration sensors to measure respective acceleration vectors; and retrieving said respiration signals by applying differential angle measurement to the acceleration vectors measured by said two acceleration sensors to extract said respiration signals. 7. The method according to claim 6 , wherein said retrieving comprises applying said differential angle measurement by measuring an angle difference between acceleration vectors of said two acceleration sensors. 8. The method according to claim 6 , further comprising using said two acceleration sensors in respiration sensing as inclinometers to reflect chest movement caused by respiration. 9. A multi-sensor device for monitoring vital body respiration signals on a body of a human or animal, the device comprising: at least two acceleration sensors each adapted to measure an acceleration vector and adapted to be placed at predetermined locations on a sternum of said body with the at least two acceleration sensors separated by the point that separates the main body of the sternum and a manubrium in such a way that an angle change induced by said vital body respiration signals differs between said at least two acceleration sensors; and a signal extractor comprising a computer programmed to extract said vital body respiration signals by applying differential angle measurement to measurement results of said at least two acceleration sensors placed at the predetermined locations. 10. The multi-sensor device according to claim 9 , wherein said at least two acceleration sensors are tri-axial accelerometers. 11. A signal extracting apparatus for use in the multi-sensor device according to claim 9 , said signal extracting apparatus being adapted to extract said vital body respiration signals by applying differential angle measurement to measurement results of said at least two acceleration sensors. 12. The device according to claim 9 , wherein the at least two acceleration sensors are configured, in respiration sensing, as inclinometers to reflect abdomen or chest movement caused by respiration or in pulse sensing to catch mechanical vibration caused by heart pumping.