Wireless communication network using frequency conversion of MIMO signals

The invention claimed is: 1. A communication network for wireless communication comprising: a base station configured for transmitting and receiving a communication signal on at least two equal-frequency MIMO-coded information channels; a wireless terminal configured for transmitting and receiving a communication signal on at least two equal-frequency MIMO-coded information channels; at least one repeater coupled between the base station and the wireless terminal, the repeater being configured for receiving, passing through and retransmitting communication signals on at least two equal-frequency MIMO-coded information channels and containing a converting device for frequency conversion of at least one information channel passed therethrough; a test receiver configured for determining unused frequency ranges that are situated outside the frequency bands allocated to mobile radio for wireless communication, the test receiver being coupled with the converting device of the repeater and the converting device configured for carrying out frequency conversion in at least one communication direction (UL, DL) to a frequency from the unused frequency ranges situated outside the frequency bands allocated to mobile radio so that the MIMO-coded information channels are transmitted using different frequencies compared to each other; the repeater being configured for transmitting the communication signal wirelessly with the at least one frequency-converted information channel in the at least one communication direction so that at least one frequency-converted MIMO-coded information channel is transported on a different frequency outside the frequency bands allocated to mobile radio. 2. The communication network of claim 1 wherein the base station comprises a further converting device for the frequency conversion of at least one information channel which is connected to the test receiver and is configured for carrying out the frequency conversion in the downlink direction to a frequency from the unused frequency ranges situated outside the frequency bands allocated to mobile radio, the converting device of the at least one repeater being configured for resetting the frequency of the frequency-converted information channel in the downlink direction (DL), and carrying out the frequency conversion of the at least one information channel into the frequency from the unused frequency ranges situated outside the frequency bands allocated to mobile radio in the uplink direction (UL). 3. The communication network of claim 1 further including, between the base station and terminal, at least two repeaters which are configured for receiving, passing through and retransmitting communication signals on multiple information channels, each repeater containing a converting device, connected to a test receiver, for frequency conversion of at least one information channel passed through in at least one communication direction to a frequency from the unused frequency ranges situated outside the frequency bands allocated to mobile radio, the converting device of the repeater on a base station side being configured for carrying out the frequency conversion of the at least one information channel to the frequency from the unused frequency ranges situated outside the frequency bands allocated to mobile radio in the downlink direction (DL) and resetting the frequency of the frequency-converted information channel in the uplink direction (UL), and the converting device of the repeater on a terminal side being configured for resetting the frequency of the frequency-converted information channel in the downlink direction (DL), and carrying out the frequency conversion of the at least one information channel to the frequency from the unused frequency ranges situated outside the frequency bands allocated to mobile radio in the uplink direction (UL). 4. The communication network of claim 3 , wherein the base station is a MIMO-capable base station and is configured for transmitting and receiving a communication signal on spatially multiple information channels, and wherein the repeater on the base station side is a MIMO-capable repeater which is configured for transmitting spatially multiple information channels in the uplink direction (UL) and receiving spatially multiple information channels in the downlink direction (DL). 5. The communication network of claim 3 , the repeater on the base station side being connected to the base station via bidirectional couplers and exchanging the communication signals optically or electrically with the base station. 6. The communication network of claim 1 wherein the terminal is a MIMO-capable terminal which is configured for transmitting and receiving a communication signal on spatially multiple information channels, and in that the at least one repeater is a MIMO-capable repeater which is configured for transmitting spatially multiple information channels in the downlink direction (DL) and receiving spatially multiple information channels in the uplink direction (UL). 7. The communication network of claim 3 wherein a test receiver is allocated to a converting device, the test receivers being connected to one another and synchronized with regard to the frequency to be selected for the frequency conversion. 8. The communication network of claim 1 wherein the test receiver is connected to a central database which stores the frequency ranges unused for wireless communication that are situated outside the frequency bands allocated to mobile radio are stored. 9. The communication network of claim 1 wherein the test receiver comprises a spectrum analyzer. 10. The communication network of claim 1 the converting device being configured for carrying out no frequency conversion for at least one of the information channels. 11. The communication network of claim 3 wherein the at least one or terminal-side repeater is used for supplying a wireless network in an indoor space. 12. The communication network of claim 1 wherein the repeater includes electronic means for suppressing a feedback of the transmitted communication signal with the communication signal passed through. 13. The communication network of claim 12 wherein the means for suppressing a feedback comprise a digital adaptive filter. 14. The communication network of claim 1 further comprising: a multiband transmission system including a master unit and at least one remote unit connected to the master unit via a common signal line; the master unit being constructed for transmitting and for receiving communication signals on multiple information channels and for connecting and decoupling the multiple information channels to/from a transmission signal, the transmission signal being conducted via the common signal line, and the at least one repeater being constructed as a component of the remote unit. 15. The communication network of claim 14 wherein the master unit and the remote unit in each case comprise an opto-electrical transducer unit which converts the transmission signal between an electrical and an optical manifestation, the transmission signal being optically transmitted on the common signal line. 16. The communication network of claim 14 wherein the master unit and the remote unit in each case comprise an analogue/digital transducer unit which converts the transmission signal between an analogue and a digital manifestation, the transmission signal being digitally transmitted on the common signal line. 17. A communication network for wireless communication comprising: a base station configured for transmitting and receivin