Joint receiver and receiving method for navigation signals located at adjacent frequencies

What is claimed is: 1. A joint receiver for navigation signals located at adjacent frequencies comprising: a receiving channel for receiving a first navigation signal and a second navigation signal which are located at adjacent frequencies; a processor for calculating a frequency estimation of a virtual wideband navigation signal constructed based on the first navigation signal and the second navigation signal, and obtaining a delay estimation of navigation based on the frequency estimation, wherein the virtual wideband navigation signal is an asymmetric navigation signal having a virtual carrier and a virtual sub-carrier, wherein the frequency estimation includes a virtual carrier frequency estimation, a virtual sub-carrier frequency estimation and a code frequency estimation of the virtual wideband navigation signal; a first correlator for generating first navigation signal correlations through correlating a local replica of the first navigation signal against the first navigation signal as received; a second correlator for generating second navigation signal correlations through correlating a local replica of the second navigation signal against the second navigation signal as received; and a joint processor for pre-processing the first navigation signal correlations and the second navigation signal correlations to compensate an asymmetry of the virtual wideband navigation signal; combining the pre-processed correlations to decouple the virtual carrier and the virtual sub-carrier of the virtual wideband navigation signal; and obtaining the virtual carrier frequency estimation, the virtual sub-carrier frequency estimation and the code frequency estimation of the virtual wideband navigation signal based on the combined pre-processed correlations. 2. The receiver as claimed in claim 1 , wherein a central frequency of the virtual carrier of the virtual wideband navigation signal is determined by an average of a received frequency of the first navigation signal and a received frequency of the second navigation signal, a central frequency of the virtual sub-carrier of the virtual wideband navigation signal is determined by half of the received frequency spacing between the first navigation signal and the second navigation signal, and a lower band of the virtual wideband navigation signal modulated with the first navigation signal is asymmetric with an upper band of the virtual wideband navigation signal modulated with the second navigation signal. 3. The receiver as claimed in claim 1 , wherein the virtual carrier frequency estimation, the virtual sub-carrier frequency estimation and the code frequency estimation obtained by the joint processor is fed back to the first correlator and the second correlator for generating the local replica of the first navigation signal and the local replica of the second navigation signal. 4. The receiver as claimed in claim 1 , wherein the joint processor comprises a calculating unit comprising instructions executable for conducting the pre-processing and combining the pre-processing correlations, wherein the pre-processing is conducted through a power compensation to the first navigation signal correlations and the second navigation signal correlations, and the preprocessing is further conducted through performing a message segregation or a sub-code segregation on the first navigation signal correlations and the second navigation signal correlations. 5. The receiver as claimed in claim 1 , wherein the joint processor comprises a carrier phase discriminator for performing a phase discrimination of the virtual carrier of the combined pre-processing correlations and a carrier phase filter for filtering a result of the phase discrimination of the virtual carrier to obtain the virtual carrier frequency estimation, and the joint processor comprises a sub-carrier phase discriminator for performing a phase discrimination of the virtual sub-carrier of the combined pre-processing correlations, and a sub-carrier phase filter for filtering a result of the phase discrimination of the virtual sub-carrier to obtain the virtual sub-carrier frequency estimation. 6. The receiver as claimed in claim 1 , wherein the joint processor comprises a code phase discriminator for performing a first code phase discrimination on the first navigation signal correlation and performing a second code phase discrimination on the second navigation signal correlation, and a result of the first code phase discrimination and a result of the second code phase discrimination are combined by the joint processor and filtered by a code filter to obtain the code frequency estimation of the virtual wideband navigation signal. 7. The receiver as claimed in claim 6 , wherein the result of the first code phase discrimination and the result of the second code phase discrimination are combined by the joint processor according to a code autocorrelation function main peak gradient and an early and late correlation spacing of the first navigation signal and a code autocorrelation function main peak gradient and an early and late correlation spacing of the second navigation signal. 8. The receiver as claimed in claim 1 , wherein the first navigation signal and the second navigation signal are a B1I signal and a B1C signal, respectively, which are broadcast in a B1 frequency band in the BeiDou Global Satellite Navigation System and are located at adjacent frequencies. 9. A joint receiving method for navigation signals located at adjacent frequencies comprising: receiving a first navigation signal and a second navigation signal which are located at adjacent frequencies; and calculating a frequency estimation of a virtual wideband navigation signal constructed based on the first navigation signal and the second navigation signal, and obtaining a delay estimation of navigation based on the frequency estimation, wherein the virtual wideband navigation signal is an asymmetric navigation signal having a virtual carrier and a virtual sub-carrier, wherein the frequency estimation comprises a virtual carrier frequency estimation, a virtual sub-carrier frequency estimation and a code frequency estimation of the virtual wideband navigation signal; obtaining first navigation signal correlations through correlating a local replica of the first navigation signal against the first navigation signal as received; obtaining second navigation signal correlations through correlating a local replica of the second navigation signal against the second navigation signal as received; and pre-processing the first navigation signal correlations and the second navigation signal correlations to compensate an asymmetry of the virtual wideband navigation signal; combining the pre-processed correlations to decouple the virtual carrier and the virtual sub-carrier of the virtual wideband navigation signal; and obtaining the virtual carrier frequency estimation, the virtual sub-carrier frequency estimation and the code frequency estimation of the virtual wideband navigation signal based on the combined pre-processed correlations, wherein the method is performed by a receiver comprising a receiving channel and a processor. 10. The receiving method as claimed in claim 9 , wherein a central frequency of the virtual carrier of the virtual wideband navigation signal is determined by an average of a received frequency of the first navigation signal and a received frequency of the second navigation signal, a central frequency of the virtual sub-carrier of the virtual wideband navigation signal is determined by half of the received frequency spacing between the first navigation signal and the second navigation signal, a lower band of the virtual wideband navigation signal modulated with the f