RADIO FREQUENCY CALIBRATION APPARATUS AND METHOD FOR MULTI-ANTENNA MOBILE COMMUNICATION SYSTEM

Abstract

There is provided to an RF calibration apparatus and method for a multi-antenna mobile communication system which calibrates a phase error and gain error of an RF path by calculating the minimum value of a sum of an initialized reference signal and a comparison signal by a simple operation and controlling the phase value of a phase converter and the gain of a variable amplifier on the RF path in calibrating the RF path of a multi-antenna mobile communication system of a TDD (Time Division Duplexing) type or FDD (Frequency Division Duplexing) type.

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4G	24/10/2017	ISLD-201801-006	Electronics and Telecommunications Research Institute	S1 TS Number: TS 136 464 Version No: Illustrative part: ---- Release: S2 TS Number: TS 136 465 Version No: Illustrative part: ---- Release: S3 TS Number: TS 123 401 Version No: Illustrative part: ---- Release: S4 TS Number: TS 136 300 Version No: Illustrative part: ---- Release: S5 TS Number: TS 136 331 Version No: Illustrative part: ---- Release: S6 TS Number: TS 136 360 Version No: Illustrative part: ---- Release: S7 TS Number: TS 136 361 Version No: Illustrative part: ---- Release: S8 TS Number: TS 136 413 Version No: Illustrative part: ---- Release: S9 TS Number: TS 136 423 Version No: Illustrative part: ---- Release: S10 TS Number: TS 136 461 Version No: Illustrative part: ---- Release: S11 TS Number: TS 136 462 Version No: Illustrative part: ---- Release: S12 TS Number: TS 136 463 Version No: Illustrative part: ---- Release: +11 -11				Yes	Basis Patent

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US2010056083A1	4G	24/10/2017	ISLD-201801-006	Electronics and Telecommunications Research Institute	S1 TS Number: TS 136 465 Version No: ---- Section No: Release : ---- S2 TS Number: TS 123 401 Version No: ---- Section No: Release : ---- S3 TS Number: TS 136 300 Version No: ---- Section No: Release : ---- S4 TS Number: TS 136 331 Version No: ---- Section No: Release : ---- S5 TS Number: TS 136 360 Version No: ---- Section No: Release : ---- S6 TS Number: TS 136 361 Version No: ---- Section No: Release : ---- S7 TS Number: TS 136 413 Version No: ---- Section No: Release : ---- S8 TS Number: TS 136 423 Version No: ---- Section No: Release : ---- S9 TS Number: TS 136 461 Version No: ---- Section No: Release : ---- S10 TS Number: TS 136 462 Version No: ---- Section No: Release : ---- S11 TS Number: TS 136 463 Version No: ---- Section No: Release : ---- S12 TS Number: TS 136 464 Version No: ---- Section No: Release : ---- +11 -11	Yes	Basis Patent
KR100758309B1	4G	24/10/2017	ISLD-201801-006	Electronics and Telecommunications Research Institute	S1 TS Number: TS 123 401 Version No: ---- Section No: Release : ---- S2 TS Number: TS 136 300 Version No: ---- Section No: Release : ---- S3 TS Number: TS 136 331 Version No: ---- Section No: Release : ---- S4 TS Number: TS 136 360 Version No: ---- Section No: Release : ---- S5 TS Number: TS 136 361 Version No: ---- Section No: Release : ---- S6 TS Number: TS 136 413 Version No: ---- Section No: Release : ---- S7 TS Number: TS 136 423 Version No: ---- Section No: Release : ---- S8 TS Number: TS 136 461 Version No: ---- Section No: Release : ---- S9 TS Number: TS 136 462 Version No: ---- Section No: Release : ---- S10 TS Number: TS 136 463 Version No: ---- Section No: Release : ---- S11 TS Number: TS 136 464 Version No: ---- Section No: Release : ---- S12 TS Number: TS 136 465 Version No: ---- Section No: Release : ---- +11 -11	No	Family Member
WO2008038988A1	4G	24/10/2017	ISLD-201801-006	Electronics and Telecommunications Research Institute	S1 TS Number: TS 123 401 Version No: ---- Section No: Release : ---- S2 TS Number: TS 136 300 Version No: ---- Section No: Release : ---- S3 TS Number: TS 136 331 Version No: ---- Section No: Release : ---- S4 TS Number: TS 136 360 Version No: ---- Section No: Release : ---- S5 TS Number: TS 136 361 Version No: ---- Section No: Release : ---- S6 TS Number: TS 136 413 Version No: ---- Section No: Release : ---- S7 TS Number: TS 136 423 Version No: ---- Section No: Release : ---- S8 TS Number: TS 136 461 Version No: ---- Section No: Release : ---- S9 TS Number: TS 136 462 Version No: ---- Section No: Release : ---- S10 TS Number: TS 136 463 Version No: ---- Section No: Release : ---- S11 TS Number: TS 136 464 Version No: ---- Section No: Release : ---- S12 TS Number: TS 136 465 Version No: ---- Section No: Release : ---- +11 -11	No	Family Member

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Claim

1. An RF (Radio Frequency) path calibration apparatus for a multi-antenna mobile communication system, the apparatus comprising:
an RF transmission path calibrating means for generating a transmission reference signal, adding the generated transmission reference signal and a second IF transmission signal passed through an RF transmission path to measure an analog power value, converting the measured analog power value into a first digital value, and then controlling the phase value of a phase converter and the gain of a variable amplifier on the transmission path by using the first digital value so that the analog power value has the minimum value; and
an RF reception path calibrating means for generating a reception reference signal, adding the generated reception reference signal and the first IF transmission signal to measure an analog power value, converting the measured analog power value into a second digital value, and then controlling the phase value of a phase converter and the gain of a variable amplifier on the reception path by using the second digital value so that the analog power value has the minimum value.', 'an RF transmission path calibrating means for generating a transmission reference signal, adding the generated transmission reference signal and a second IF transmission signal passed through an RF transmission path to measure an analog power value, converting the measured analog power value into a first digital value, and then controlling the phase value of a phase converter and the gain of a variable amplifier on the transmission path by using the first digital value so that the analog power value has the minimum value; and', 'an RF reception path calibrating means for generating a reception reference signal, adding the generated reception reference signal and the first IF transmission signal to measure an analog power value, converting the measured analog power value into a second digital value, and then controlling the phase value of a phase converter and the gain of a variable amplifier on the reception path by using the second digital value so that the analog power value has the minimum value.

2. The apparatus of claim 1, wherein the transmission reference signal has the same amplitude as a first IF transmission signal but has a phase difference of 180 degrees, and the reception reference signal has the same amplitude as a third IF transmission signal leaked to an RF reception path but has a phase difference of 180 degrees.

3. The apparatus of claim 1, wherein the RF transmission and reception path calibrating means control the phase value of the phase converter and the gain of the variable amplifier so that the sum or vector sum of the transmission reference signal and the second IF transmission signal passed through the RF transmission path is minimized and the sum of the reception reference signal and the first IF transmission signal is minimized.

4. The apparatus of claim 1, wherein the apparatus includes components of the number corresponding to the number of antennas, and
wherein the corresponding transmission or reception path is calibrated by using a digital value from each signal processing unit.', 'wherein the corresponding transmission or reception path is calibrated by using a digital value from each signal processing unit.

5. The apparatus of claim 1, wherein the RF transmission path calibrating means includes:
a first branching means for branching an IF transmission signal from a digital IF;
a second branching means for branching an IF transmission signal passed through an RF transmission path;
a transmission reference signal generating means for generating a transmission reference signal that has the same amplitude as the IF transmission signal branched through the first branching means but has a phase difference of 180 degrees;
a first signal processing means for adding the transmission reference signal generated from the transmission reference signal generating means and the IF transmission signal branched by the second branching means, measuring an analog power value, and then converting the same into a digital value; and
a first controller for controlling the phase value of the phase converter and the gain of the variable amplifier on the transmission path by using the digital value from the first signal processing means so that the measured power value has the minimum value.', 'a first branching means for branching an IF transmission signal from a digital IF;', 'a second branching means for branching an IF transmission signal passed through an RF transmission path;', 'a transmission reference signal generating means for generating a transmission reference signal that has the same amplitude as the IF transmission signal branched through the first branching means but has a phase difference of 180 degrees;', 'a first signal processing means for adding the transmission reference signal generated from the transmission reference signal generating means and the IF transmission signal branched by the second branching means, measuring an analog power value, and then converting the same into a digital value; and', 'a first controller for controlling the phase value of the phase converter and the gain of the variable amplifier on the transmission path by using the digital value from the first signal processing means so that the measured power value has the minimum value.

6. The apparatus of claim 5, wherein the transmission reference signal generating means includes:
a variable attenuator for controlling the gain so that the transmission reference signal has the same amplitude as the corresponding IF transmission signal, and a phase converter for controlling the transmission reference signal to have a phase difference of 180 degrees with the corresponding IF transmission signal, wherein the phase converter is provided with a delay buffer for temporal synchronization, for accurate comparison with the signal down-converted through the RF transmission path.', 'a variable attenuator for controlling the gain so that the transmission reference signal has the same amplitude as the corresponding IF transmission signal, and a phase converter for controlling the transmission reference signal to have a phase difference of 180 degrees with the corresponding IF transmission signal, wherein the phase converter is provided with a delay buffer for temporal synchronization, for accurate comparison with the signal down-converted through the RF transmission path.

7. The apparatus of claim 5, wherein the first signal processing means includes:
a first adder for adding the transmission reference signal generated from the transmission reference signal generator and the IF transmission signal branched by the second branching means;
a first power measuring device for measuring the power value of the signal added in the first adder; and
a first A/D converter for converting the analog power value measured in the first power measuring device into a digital value.', 'a first adder for adding the transmission reference signal generated from the transmission reference signal generator and the IF transmission signal branched by the second branching means;', 'a first power measuring device for measuring the power value of the signal added in the first adder; and', 'a first A/D converter for converting the analog power value measured in the first power measuring device into a digital value.

8. The apparatus of claim 1, wherein the RF reception path calibrating means includes:
a first branching means for branching an IF transmission signal from a digital IF;
a third branching means for branching an IF transmission signal leaked to an RF reception path;
a reception reference signal generating means for generating a reception reference signal that has the same amplitude as the IF transmission signal branched through the fourth branching means but has a phase difference of 180 degrees;
a second signal processing means for adding the reception reference signal generated from the reception reference signal generating means and the IF transmission signal branched by the third branching means, measuring an analog power value, and then converting the same into a digital value; and
a second controller for controlling the phase value of the phase converter and the gain of the variable amplifier on the reception path by using the digital value from the second signal processing means so that the measured power value has the minimum value.', 'a first branching means for branching an IF transmission signal from a digital IF;', 'a third branching means for branching an IF transmission signal leaked to an RF reception path;', 'a reception reference signal generating means for generating a reception reference signal that has the same amplitude as the IF transmission signal branched through the fourth branching means but has a phase difference of 180 degrees;', 'a second signal processing means for adding the reception reference signal generated from the reception reference signal generating means and the IF transmission signal branched by the third branching means, measuring an analog power value, and then converting the same into a digital value; and', 'a second controller for controlling the phase value of the phase converter and the gain of the variable amplifier on the reception path by using the digital value from the second signal processing means so that the measured power value has the minimum value.', '9. The apparatus of claim 8, wherein the reception reference signal generating means includes:
a variable attenuator for controlling the gain so that the reception reference signal has the same amplitude as the corresponding IF transmission signal; and
a phase converter for controlling the reception reference signal to have a phase difference of 180 degrees with the corresponding IF transmission signal, wherein the phase converter is provided with a delay buffer for temporal synchronization, for accurate comparison with the signal down-converted through the RF reception path.', 'a variable attenuator for controlling the gain so that the reception reference signal has the same amplitude as the corresponding IF transmission signal; and', 'a phase converter for controlling the reception reference signal to have a phase difference of 180 degrees with the corresponding IF transmission signal, wherein the phase converter is provided with a delay buffer for temporal synchronization, for accurate comparison with the signal down-converted through the RF reception path.', '10. The apparatus of claim 8, wherein the second signal processing means includes:
a second adder for adding the reception reference signal generated from the reception reference signal generator and the IF transmission signal branched by the third branching means;
a second power measuring device for measuring the power value of the signal added in the second adder; and
a second A/D converter for converting the analog power value measured in the second power measuring device into a digital value.', 'a second adder for adding the reception reference signal generated from the reception reference signal generator and the IF transmission signal branched by the third branching means;', 'a second power measuring device for measuring the power value of the signal added in the second adder; and', 'a second A/D converter for converting the analog power value measured in the second power measuring device into a digital value.', '11. An RF path calibration method for a multi-antenna mobile communication system, the method comprising the steps of:
generating a transmission reference signal that has the same amplitude as a first IF transmission signal but has a phase difference of 180 degrees, adding the generated transmission reference signal and a second IF transmission signal passed through an RF transmission path to measure an analog power value, converting the measured analog power value into a first digital value, and controlling the phase value of a phase converter and the gain of a variable amplifier on the transmission path by using the first digital value so that the analog power value has the minimum value; and
generating a reception reference signal that has the same amplitude as a third IF transmission signal leaked to an RF reception path but has a phase difference of 180 degrees, adding the generated reception reference signal and the first IF transmission signal to measure an analog power value, converting the measured analog power value into a second digital value, and controlling the phase value of a phase converter and the gain of a variable amplifier on the reception path by using the second digital value so that the analog power value has the minimum value.', 'generating a transmission reference signal that has the same amplitude as a first IF transmission signal but has a phase difference of 180 degrees, adding the generated transmission reference signal and a second IF transmission signal passed through an RF transmission path to measure an analog power value, converting the measured analog power value into a first digital value, and controlling the phase value of a phase converter and the gain of a variable amplifier on the transmission path by using the first digital value so that the analog power value has the minimum value; and', 'generating a reception reference signal that has the same amplitude as a third IF transmission signal leaked to an RF reception path but has a phase difference of 180 degrees, adding the generated reception reference signal and the first IF transmission signal to measure an analog power value, converting the measured analog power value into a second digital value, and controlling the phase value of a phase converter and the gain of a variable amplifier on the reception path by using the second digital value so that the analog power value has the minimum value.', '12. The method of claim 11, wherein the transmission reference signal generating step includes the steps of:
firstly-branching an IF transmission signal from a digital IF;
secondary-branching the IF transmission signal passed through an RF transmission path;
generating a transmission reference signal that has the same amplitude as the IF transmission signal branched through the first branching step but has a phase difference of 180 degrees;
adding the generated transmission reference signal and the IF transmission signal branched by the second branching step, measuring an analog power value, and then converting the same into a first digital value; and
controlling the phase value of the phase converter and the gain of the variable amplifier on the transmission path by using the first digital value so that the measured power value has the minimum value.', 'firstly-branching an IF transmission signal from a digital IF;', 'secondary-branching the IF transmission signal passed through an RF transmission path;', 'generating a transmission reference signal that has the same amplitude as the IF transmission signal branched through the first branching step but has a phase difference of 180 degrees;', 'adding the generated transmission reference signal and the IF transmission signal branched by the second branching step, measuring an analog power value, and then converting the same into a first digital value; and', 'controlling the phase value of the phase converter and the gain of the variable amplifier on the transmission path by using the first digital value so that the measured power value has the minimum value.', '13. The method of claim 11, wherein the second branching step includes the steps of: firstly-branching an IF transmission signal from a digital IF;
thirdly-branching the IF transmission signal leaked to an RF reception path;
generating a reception reference signal that has the same amplitude as the IF transmission signal branched through the third branching step but has a phase difference of 180 degrees;
adding the generated reception reference signal and the IF transmission signal branched by the first branching step, measuring an analog power value, and then converting the same into a second digital value; and
controlling the phase value of the phase converter and the gain of the variable amplifier on the reception path by using the second digital value so that the measured power value has the minimum value.', 'thirdly-branching the IF transmission signal leaked to an RF reception path;', 'generating a reception reference signal that has the same amplitude as the IF transmission signal branched through the third branching step but has a phase difference of 180 degrees;', 'adding the generated reception reference signal and the IF transmission signal branched by the first branching step, measuring an analog power value, and then converting the same into a second digital value; and', 'controlling the phase value of the phase converter and the gain of the variable amplifier on the reception path by using the second digital value so that the measured power value has the minimum value.']

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