METHOD FOR ENABLING COHERENT RECEPTION OF A RADIO SIGNAL AND RADIO RECEIVER FOR COHERENT RECEPTION OF A RADIO SIGNAL

Abstract

An example method for enabling coherent reception of a radio signal includes, in some implementations, tuning a radio receiver to a first receiver frequency, generating within the radio receiver a test signal having a first test frequency, and measuring a first phase of the test signal while the radio receiver is tuned to the first receiver frequency. The example method also includes tuning the radio receiver to a second receiver frequency, which is different from the first receiver frequency, measuring a second phase of the test signal while the radio receiver is tuned to the second receiver frequency, and calculating a phase relationship depending on the first and second phases of the test signal. A radio receiver for coherent reception of a radio signal also is disclosed.

Claims

1. A method for enabling coherent reception of a radio signal comprising: a) tuning a radio receiver to a first receiver frequency, b) generating within the radio receiver a test signal having a first test frequency, c) measuring a first phase of the test signal while the radio receiver is tuned to the first receiver frequency, d) tuning the radio receiver to a second receiver frequency, which is different from the first receiver frequency, e) measuring a second phase of the test signal while the radio receiver is tuned to the second receiver frequency, f) calculating a phase relationship depending on the first and second phases of the test signal.

2. The method according to claim 1, wherein the first test frequency of the test signal lies within an observation frequency range of the radio receiver.

3. The method according to claim 2, wherein the radio signal, which is enabled to be received coherently, has a frequency spectrum which is wider than the observation frequency range of the radio receiver while the radio receiver is tuned to one of the first or the second receiver frequencies.

4. The method according to claim 2, including repeating a) through f), and using in each repetition the second receiver frequency of a respective previous repetition as the first receiver frequency until a tunable frequency range of the radio receiver is covered.

5. The method according to claim 4, wherein in each repetition the first test frequency of the test signal is adapted to the first or second receiver frequency of the radio receiver, such that the first test frequency of the test signal lies within the observation frequency range of the radio receiver while the radio receiver is tuned to one of the first or the second receiver frequencies.

6. The method according to claim 4, wherein in each repetition the first test frequency of the test signal has a frequency value that is different from a frequency value of the first test frequency of the previous repetition.

7. The method according to claim 1, wherein the first test frequency of the test signal is represented at least by a test carrier frequency, and wherein the first and the second receiver frequencies are each represented at least by a receiver carrier frequency.

8. The method according to claim 7, wherein generating the test signal comprises: generating a test baseband frequency of the test signal, generating the test carrier frequency, and modulating the test carrier frequency with the test baseband frequency.

9. A radio receiver for coherent reception of a radio signal, the radio receiver comprising: a receiver unit, a sender unit, a connector unit, and a control unit, wherein the receiver unit is configured to generate at least a first receiver frequency and a second receiver frequency, which is different from the first receiver frequency, to measure a first phase of a test signal during generation of the first receiver frequency and to measure a second phase of the test signal during generation of the second receiver frequency, wherein the sender unit is configured to generate the test signal, the test signal having a first test frequency, wherein the connector unit is coupled to the sender unit and the receiver unit and is configured to provide the test signal from the sender unit to the receiver unit, wherein the control unit is coupled to the sender unit, the receiver unit and the connector unit for respective control thereof, the control unit being further configured to tune the receiver unit to the first and subsequently to the second receiver frequency and to calculate a phase relationship from the measured first phase and the measured second phase of the test signal.

10. The radio receiver according to claim 9, wherein the first test frequency of the test signal lies within an observation frequency range of the radio receiver.

11. The radio receiver according to claim 10, wherein the control unit is further configured to tune the first test frequency of the sender unit to a different value after calculating the phase relationship, the different value lying within the observation frequency range of the receiver unit.

12. The radio receiver according to claim 9, wherein the receiver unit comprises: a receiver oscillator configured to generate the first and the second receiver frequency, and a measurement unit coupled to the receiver oscillator, the measurement unit being configured to measure the first and the second phase of the test signal.

13. The radio receiver according to claim 9, wherein the sender unit comprises: a sender oscillator configured to generate at least the first test frequency, wherein the first test frequency of the test signal is represented at least by a test carrier frequency.

14. The radio receiver according to claim 13, wherein the sender unit further comprises: a tone generator configured to generate a test baseband frequency of the test signal, and a modulator configured to generate the test signal by modulation of the test carrier frequency with the test baseband frequency and to provide the test signal to the connector unit.

15. The radio receiver according to claim 9, wherein each of the first and the second receiver frequencies is represented at least by a receiver carrier frequency.

Description

[0049] The text below explains the proposed method and radio receiver in detail using exemplary embodiments with reference to the drawings. Components and circuit elements that are functionally identical or have an identical effect bear identical reference numbers. Insofar as circuit parts or components correspond to one another in their function, a description of them will not be repeated in each of the following figures. Therein,

[0050] FIG. 1 shows an exemplary embodiment of a method as proposed,

[0051] FIG. 2 shows a first exemplary embodiment of a radio receiver as proposed, and

[0052] FIG. 3 shows a second exemplary embodiment of a radio receiver as proposed.

[0053] FIG. 1 shows an exemplary embodiment of a method as proposed. According to the depicted embodiment the method for enabling coherent reception of a radio signal comprises the following steps: [0054] a) tuning a radio receiver to a first receiver frequency, [0055] b) generating within the radio receiver a test signal having a first test frequency, [0056] c) measuring a first phase of the test signal while the radio receiver is tuned to the first receiver frequency, [0057] d) tuning the radio receiver to a second receiver frequency, which is different from the first receiver frequency, [0058] e) measuring a second phase of the test signal while the radio receiver is tuned to the second receiver frequency, [0059] f) calculating a phase relationship depending on the first and second phases of the test signal.

[0060] According to the proposed method the radio receiver is tuned to the first receiver frequency and the test signal having the first test frequency is generated internally, i.e. within the radio receiver. The first phase of the test signal is measured. Then the radio receiver is tuned to the second receiver frequency and the second phase of the test signal is measured, while the test signal continues to be generated. The phase relationship depending on or in function of the measured first and second phases of the test signal is calculated subsequently.

[0061] The calculation or determination of the phase relationship enables coherent reception of the radio signal, as the phase of the radio receiver when changing from the first receiver frequency to the second receiver frequency is known. Thereby, the bandwidth for which coherent reception of the radio signal is enabled is doubled.

[0062] As already mentioned above, the sequence of steps a) and b) does not matter. Consequently, step a) may be performed before or after step b). Furthermore, the test signal generated in step b) remains constantly on during performance of steps c), d) and e).

[0063] Therein, the first test frequency of the test signal lies with an observation frequency range of the radio receiver. The observation frequency range is characterized by the first or the second receiver frequency. The first and second receiver frequencies may each comprise at least a carrier frequency, for instance, a carrier frequency according to the LTE specification. In an exemplary embodiment the observation frequency range amounts to a bandwidth of 20 megahertz.

[0064] According to the proposed method the test signal generated in step b) is looked at or observed twice, first in step c) while the receiver is tuned to the first receiver frequency, e.g. X1, and second in step e) while the receiver is tuned to the second receiver frequency, e.g. X2. Tuning of the receiver from the first receiver frequency X1 to the second receiver frequency X2 typically cannot be effected in zero time or without introducing an unknown phase relationship between the first and second receiver frequencies. Therefore, without any further countermeasures, the phase relationship between two measurements using different receiver frequencies would be lost. This is overcome by the proposed method, in that the internally generated test signal remains constantly present and its phase is measured at the first and the second receiver frequency. The phase relationship is calculated from the measured first and second phases of the test signal.

[0065] For example, the test signal is generated by modulating or mixing a first test carrier frequency Y1 with a test baseband frequency Z1, such that the first test frequency results e.g. to Y1+Z1.

[0066] Optionally, steps a) to f) may be repeated for further increasing the bandwidth of the radio signal which is enabled to be received coherently. For this, after having performed steps a) to f) a first time using X1 as the first receiver frequency and X2 as the second receiver frequency and e.g. Y1+Z1 as the first test frequency, steps a) to f) are performed a second time using the second receiver frequency X2 of the previous run or repetition as the first receiver frequency in step a) of the new repetition, using another receiver frequency X3 as the second receiver frequency in step d) of the new repetition and potentially then using a second test frequency, e.g. Y2+Z1, comprising a second test carrier frequency Y2 and the test baseband frequency Z1, when generating the test signal in step b) of the new repetition. Therein, the second test frequency Y2+Z1 lies within the observation frequency range of the radio receiver when being tuned to the first and the second receiver frequencies X2 and X3 when the method is performed a second time in the new repetition.

[0067] Consequently, with each repetition of method steps a) to f) as proposed, the bandwidth of the radio signal which is enabled to be received coherently is further increased.

[0068] FIG. 2 shows a first exemplary embodiment of a radio receiver as proposed. The radio receiver comprises a receiver unit 10 that can be coupled to an antenna 11, a sender unit 30, a connector unit 40 and a control unit 50. The receiver unit 10 is configured to generate at least a first receiver frequency X1 and a second receiver frequency X2, which is different from the first receiver frequency X1. The receiver unit 10 is further configured to measure a first phase of a test signal during generation of the first receiver frequency X1 and to measure a second phase of the test signal during generation of the second receiver frequency X2. The sender unit 30 is configured to generate the test signal, the test signal having a first test frequency, e.g. Y1+Z1. The connector unit 40 is coupled to the sender unit 30 and the receiver unit 10 and is configured to provide the test signal from the sender unit 30 to the receiver unit 10, e.g. directly. The control unit 50 is coupled to the sender unit 30, the receiver unit 10 and to the connector unit 40 for respective control thereof. The control unit 50 is further configured to tune the receiver unit 10 to the first and subsequently to the second receiver frequency X1, X2 and to calculate a phase relationship from the measured first phase and the measured second phase of the test signal.

[0069] The control unit 50 tunes the receiver unit 10 to the first receiver frequency X1 and causes the sender unit 30 to generate the test signal having the first test frequency Y1+Z1. The receiver unit 10 measures the first phase of the test signal during generation of the first receiver frequency X1. The control unit 50 tunes the receiver unit 10 to the second receiver frequency X1, while the test signal is still being generated. The receiver unit 10 measures the second phase of the test signal during generation of the second receiver frequency X2. The control unit 50 calculates the phase relationship from the measured first and second phases of the test signal.

[0070] Using the radio receiver as proposed enables increasing the bandwidth of a radio signal which can be received coherently. Details concerning the first and second receiver frequencies, as well as the first test frequency as described above with reference to FIG. 1 also apply to the description of FIG. 2 and are not repeated again.

[0071] Optionally, the control unit 50 is further configured to tune the test frequency of the sender unit 30 to a different value after calculating the phase relationship. As detailed above, the first test frequency in a first run may be tuned to Y1+Z1. In a second run the test frequency then is tuned to the different value Y2+Z1 of a second test frequency. This different value still lies within the observation frequency range of the receiver unit 10.

[0072] FIG. 3 shows a second exemplary embodiment of a radio receiver as proposed. FIG. 3 coincides with FIG. 2 and additionally discloses more details of an exemplary implementation of the radio receiver as proposed.

[0073] According to FIG. 3 the receiver unit 10 comprises a receiver oscillator 12 which is configured to generate the first and the second receiver frequency X1, X2. The receiver oscillator 12 may be realized as a synthesizer or local oscillator as known to those skilled in the art. The receiver unit 10 further comprises a measurement unit 13 which is configured to measure the first and the second phases of the test signal. For this purpose the measurement unit 13 comprises different components for processing a received signal. For example, the analog signal is amplified by a transconductance amplifier, TCA, and filtered by a baseband filter. Subsequently the signal is converted to a digital signal in an analog-to-digital converter, ADC. The digital signal is further processed in a digital front end, DFE, which e.g. comprises a digital mixer, one or more digital filters and one or more digital amplifiers. At the output of the DFE, the measured first and second phases of the test signal are provided. For example, the measurement of the first and the second phases is performed in the DFE under the control of the control unit 50.

[0074] The sender unit 30 comprises a sender oscillator 31, which is configured to generate at least the first test frequency or the test carrier frequency Y1. Optionally, the sender unit 30 further comprises a tone generator 32 which is configured to generate a test baseband frequency Z1 of the test signal. In the example displayed in FIG. 3 the test baseband frequency Z1 is digitally generated, processed by a digital front end, DFE, converted into an analog baseband frequency by digital-to-analog converter DAC and turned into the test baseband frequency Z1. The sender unit 30 further comprises a modulator 33 which is configured to generate the test signal by modulation or mixing of the test carrier frequency Y1 with the test baseband frequency Z1 and to provide the test signal, having the resulting test frequency Y1+Z1, to the connector unit 40. If the test carrier frequency is tuned to Y2, the test frequency results to Y2+Z1.

[0075] The connector unit 40 provides the test signal to the receiver unit 10, e.g. directly.

[0076] In the depicted exemplary implementation the test signal is provided to the receiver unit 10 by way of a low noise amplifier, LNA, switch. The test signal may further undergo translational filtering before being supplied to a frequency mixer 14. The frequency mixer 14 mixes the test signal with the first or the second receiver frequency. The phase of the resulting signal is subsequently measured in the measurement unit 13 as described above.

[0077] The connector unit 40 internally, i.e. within the radio receiver, connects the sender unit 30 to the receiver unit 10. By this, the same test signal, i.e. its phase, can be measured using different receiver frequencies, i.e. the first and the second receiver frequency X1, X2. A phase relationship between different modes of the receiver oscillator 12, i.e. when it is tuned to the first or the second receiver frequency X1, X2, can be established. A radio signal which may subsequently be received via antenna 11 is enabled to be received coherently over a wider frequency range.

[0078] The method as described above may be implemented by the radio receiver as depicted in FIG. 2 or 3. The method may be repeated various times until a tunable frequency range of the radio receiver, specifically the receiver unit 10 of the radio receiver, more specifically the receiver oscillator 12, is reached. In an example, a typical analog bandwidth of the receiver unit 10 amounts to 20 megahertz. A typical tuning range of the receiver oscillator 12 amounts to approximately 1 gigahertz. With a state-of-the-art radio receiver consequently a radio signal having a bandwidth of 20 megahertz can be coherently received. With the proposed radio receiver a signal of up to 1 gigahertz bandwidth is enabled to be received coherently. This amounts to a coverage improvement of about 50 times.

[0079] It will be appreciated that the invention is not limited to the disclosed embodiments and to what has been particularly shown and described hereinabove. Rather, features recited in separate dependent claims or in the description may advantageously be combined. Furthermore, the scope of the invention includes those variations and modifications which will be apparent to those skilled in the art and fall within the scope of the appended claims. The term “comprising” used in the claims or in the description does not exclude other elements or steps of a corresponding feature or procedure. In case that the terms “a” or “an” are used in conjunction with features, they do not exclude a plurality of such features. Moreover, any reference signs in the claims should not be construed as limiting the scope.

REFERENCE LIST

[0080] 10 receiver unit [0081] 11 antenna [0082] 12 oscillator [0083] 13 measurement unit [0084] 14 mixer [0085] 30 sender unit [0086] 31 oscillator [0087] 32 tone generator [0088] 33 modulator [0089] 40 connector unit [0090] 50 control unit [0091] X1, X2, Y1, Y2, Z1 frequency