Digital phase shifter

What is claimed is: 1. A digital phase shifter, comprising: a logic control circuit; wherein the logic control circuit is configured to: receive an (N+2)-bit digital control source signal; generated four N-bit digital phase shift control signals according to the (N+2)-bit digital control source signal; and output the four N-bit digital phase shift control signals, wherein low-order N bits of the (N+2)-bit digital control source signal are used to control magnitudes of the four N-bit digital phase shift control signals, wherein high-order 2 bits of the (N+2)-bit digital control source signal are used to control a correspondence between the four N-bit digital phase shift control signals and four output ends of the logic control circuit, and wherein N is natural number; at least four current digital-to-analog converters coupled to the logic control circuit, wherein the at least four current digital-to-analog converters are each configured to: receive one of the four N-bit digital phase shift control signals; convert the four N-bit digital phase shift control signals into four current signals by means of digital-to-analog conversion; and output the four current signals; at least four amplifiers coupled to the at least four current digital-to-analog converters, wherein the at least four amplifiers are configured to: receive respective four orthogonal input signals; perform gain control on the four orthogonal input signals using the four current signals to obtain four amplified signals; and output the four amplified signals, wherein each amplifier corresponds to one input signal and one current signal; and a vector summation circuit coupled to the at least four amplifiers, wherein the vector summation circuit is configured to: perform vector summation on the four amplified signals to obtain a phase-shifted signal; and output the phase-shifted signal. 2. The digital phase shifter according to claim 1 , wherein the logic control circuit controls, according to four different values of the high-order 2 bits in the (N+2)-bit digital control source signal, the four output ends to operate in four different output states, wherein in any output state, an N-bit digital phase shift control signal that is output by one of the four output ends is C 1 , wherein an N-bit digital phase shift control signal that is output by another output end is C 2 , wherein N-bit digital phase shift control signals that are output by other two output ends are 0, wherein in different output states, different output ends output the N-bit digital phase shift control signal, wherein C 1 is the same as the low-order N bits of the (N+2)-bit digital control source signal, and wherein C 2 and C 1 satisfy C 2 =√{square root over ((2 N −1) 2 −C 1 2 )}. 3. The digital phase shifter according to claim 2 , wherein the phase-shifted signal has four phase shift ranges, wherein the four phase shift ranges are in one-to-one correspondence with the four output states of the logic control circuit, and wherein the four phase shift ranges are 0 degree (°) to 90°, 90° to 180°, 180° to 270°, and 270° to 360°. 4. The digital phase shifter according to claim 1 , wherein each current digital-to-analog converter comprises: N transistors connected in parallel; sources of the N transistors are grounded; drains of the N transistors are connected, and used as an output end of each current digital-to-analog converter; and gates of the N transistors are used as input ends of each current digital-to-analog converter, wherein each input end receives one bit of digital signal in the N-bit digital phase shift control signal, for controlling a connection and disconnection between a drain and a source of a corresponding transistor. 5. The digital phase shifter according to claim 4 , wherein a magnitude of a current that is output by a drain of any transistor in each current digital-to-analog converter when the transistor is turned on is in direct proportion to a weight of a bit of a digital phase shift control signal that is input to a gate of the transistor. 6. The digital phase shifter according to claim 5 , wherein the current that is output by the drain of any transistor in each current digital-to-analog converter when the transistor is turned on is I i =2 i I 0 , wherein i is the bit of the digital phase shift control signal that is input to the gate of any transistor, wherein i=0, 1, 2, . . . , or N−1, and wherein I 0 is a preset reference current value. 7. The digital phase shifter according to claim 1 , wherein each amplifier comprises a differential transistor pair, wherein sources of the differential transistor pair are connected; and used as a gain control end of each amplifier, wherein gates of the differential transistor pair are used as input ends of the each amplifier and receive two phase-inverted input signals in the four orthogonal input signals, and wherein drains of the differential transistor pair are used as output ends of each amplifier and output a pair of differential signals that are obtained after the two phase-inverted input signals are amplified. 8. The digital phase shifter according to claim 1 , further comprising a digital calibration circuit, wherein an output end of the digital calibration circuit is connected to an input end of the logic control circuit, and wherein the digital calibration circuit is configured to generate the (N+2)-bit digital control source signal according to a digital pre-distortion algorithm. 9. The digital phase shifter according to claim 8 , wherein the digital calibration circuit is reconfigurable; and comprises any of a processing chip storing calibration software, a field-programmable gate array, or an on-chip digital circuit into which the digital phase shifter is to be integrated. 10. The digital phase shifter according to claim 8 , wherein the digital calibration circuit is configured to: determine, according to a preset control code table, a control code corresponding to a phase of a to-be-output phase-shifted signal; and use the control code as the (N+2)-bit digital control source signal.