Predistortion for hybrid digital/analog precoders
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| Název: | Predistortion for hybrid digital/analog precoders |
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| Patent Number: | 9,762,302 |
| Datum vydání: | September 12, 2017 |
| Appl. No: | 15/171198 |
| Application Filed: | June 02, 2016 |
| Abstrakt: | A 5G base station transmitter at least partially precodes data for beam forming, and generates digital precoded baseband signals. Cross product circuitry coupled to the digital precoder, generates digital cross products of the digital precoded baseband signals. Both the baseband signals and the cross products are put through digital-to-analog converters (DACs), then provided to an analog non-linear precoder. The analog non-linear precoder combines the analog baseband signals, the cross products, with pre-distortion and precoder coefficients to generate a signal that is pre-compensated for power amplifier non-linearity. The pre-compensated signal is amplified by the power amplifier and transmitted via a phased antenna array. The number of extra DACs required for inserting pre-distortion when a hybrid digital/analog precoder is used can be limited to approximately [mathematical expression included] where NRF is the number of outputs of the digital precoder. This is significantly fewer than the number of extra DACs used by other methods. |
| Inventors: | Maxlinear Asia Singapore Private Limited (Singapore, SG) |
| Assignees: | Maxlinear Asia Singapore Pte Ltd (Singapore, SG) |
| Claim: | 1. An analog precoder comprising: at least one coefficient input configured to receive coefficients configured to introduce pre-distortion compensating for nonlinearities in a plurality of Radio Frequency (RF) power amplifiers; a plurality of outputs configured to transmit a plurality of pre-compensated signals to the plurality of RF power amplifiers; for each of the plurality of outputs: a plurality of baseband inputs configured to receive, from a plurality of digital-to-analog converters: analog-converted baseband signals from a digital precoder; analog-converted cross-products of the baseband signals; and processing circuitry configured to combine the coefficients with the analog-converted baseband signals and the analog-converted cross-products to generate a pre-compensated signal of the plurality of pre-compensated signals. |
| Claim: | 2. The analog precoder of claim 1 , wherein the plurality of baseband inputs includes: substantially N RF first inputs configured to receive the analog-converted baseband signals, wherein N RF is the number of analog-converted baseband signals processed by the digital precoder; and substantially [mathematical expression included] additional inputs configured to receive the analog-converted cross products. |
| Claim: | 3. The analog precoder of claim 1 , the processing circuitry further comprising: a first plurality of complex multipliers associated with the analog-converted baseband signals; and a second plurality of complex multipliers associated with the analog-converted cross-products of the baseband signals. |
| Claim: | 4. The analog precoder of claim 3 , wherein: the first plurality of complex multipliers includes substantially N RF complex multipliers, wherein N RF is the number of analog-converted baseband signals processed by the digital precoder; and the second plurality of complex multipliers includes substantially N RF /4*(2*N RF +7)+1 additional inputs. |
| Claim: | 5. The analog precoder of claim 1 , wherein the coefficients include: precoder coefficients; and separate digital pre-distortion coefficients. |
| Claim: | 6. The analog precoder of claim 5 , wherein the precoder coefficients are at least partially calculated in a baseband chip and passed to the analog precoder. |
| Claim: | 7. The analog precoder of claim 1 , wherein the at least one coefficient input further comprises: an input configured to receive adaptive digital pre-distortion coefficients generated based on feedback from the RF power amplifiers. |
| Claim: | 8. A base station transmitter comprising: digital baseband transmitter circuitry including: a digital precoder configured to at least partially precode data for beam forming and output a plurality of digital precoded baseband signals; cross product circuitry coupled to the digital precoder, the cross product circuitry configured to generate digital cross products of the digital precoded baseband signals; a plurality of digital-to-analog converters coupled to outputs of the digital precoder and the cross product circuitry and configured to output analog-converted baseband signals and analog-converted cross-product signals; Radio Frequency (RF) up-conversion circuitry including: an analog non-linear precoder including a plurality of outputs, for each output of the analog non-linear precoder: a plurality of baseband inputs coupled to the digital baseband transmitter, the plurality of baseband inputs configured to receive the analog-converted baseband signals and analog-converted cross-product signals; at least one coefficient input configured to receive coefficients configured to introduce pre-distortion compensating for nonlinearities in an RF power amplifier of a plurality of RF power amplifiers; processing circuitry configured to combine the coefficients with the analog-converted baseband signals and the analog-converted cross-product signals to generate a pre-compensated signal; the plurality of RF power amplifiers coupled to the analog non-linear precoder; and a phased antenna array coupled to the RF up-conversion circuitry. |
| Claim: | 9. The base station transmitter of claim 8 , wherein the plurality of digital-to-analog converters includes: substantially N RF first digital-to-analog converters per output of the analog non-linear precoder, the first digital-to-analog converters associated with the analog-converted baseband signals, wherein N RF is the number of analog-converted baseband signals processed by the digital precoder; and substantially [mathematical expression included] additional digital-to-analog converters per output of the analog non-linear precoder, the additional digital-to-analog converters associated with the analog-converted cross-product signals. |
| Claim: | 10. The base station transmitter of claim 8 , the processing circuitry further comprising: a first plurality of complex multipliers associated with the analog-converted baseband signals; and a second plurality of complex multipliers associated with the analog-converted cross-product signals. |
| Claim: | 11. The base station transmitter of claim 10 , wherein: the first plurality of complex multipliers includes substantially N RF complex multipliers, wherein N RF is the number of analog-converted baseband signals processed by the digital precoder; and the second plurality of complex multipliers includes substantially N RF /4*(2*N RF +7)+1 additional inputs. |
| Claim: | 12. The base station transmitter of claim 8 , wherein the coefficients include: precoder coefficients; and digital pre-distortion coefficients. |
| Claim: | 13. The base station transmitter of claim 12 , the digital baseband transmitter circuitry further configured to: calculate at least one precoder coefficient; and transmit the at least one precoder coefficients to the analog non-linear precoder. |
| Claim: | 14. The base station transmitter of claim 8 , further comprising: circuitry configured to generate adaptive digital pre-distortion coefficients based on feedback from the plurality of RF power amplifiers. |
| Claim: | 15. An analog precoder chip comprising: at least one coefficient input configured to receive at least pre-distortion coefficients; a plurality of outputs configured to transmit a pre-compensated signal to Radio Frequency (RF) power amplifier of a plurality of RF power amplifiers; for each of the plurality of outputs: a plurality of first inputs configured to receive analog-converted digital baseband signals from a digital precoder; at least one second input configured to receive analog-converted cross-products of the digital baseband signals; and processing circuitry configured to combine the pre-distortion coefficients with the analog-converted baseband signals and the analog-converted cross-products to generate the pre-compensated signal. |
| Claim: | 16. The analog precoder chip of claim 15 , further comprising: substantially N RF first inputs, wherein N RF is the number of analog-converted baseband signals processed by the digital precoder; and substantially [mathematical expression included] second inputs. |
| Claim: | 17. The analog precoder chip of claim 15 , the processing circuitry further comprising: a first plurality of complex multipliers associated with the analog-converted digital baseband signals; and a second plurality of complex multipliers associated with the analog-converted digital cross-products of the digital baseband signals. |
| Claim: | 18. The analog precoder chip of claim 17 , wherein: the first plurality of complex multipliers includes substantially N RF complex multipliers wherein N RF is the number of analog-converted baseband signals processed by the digital precoder; and the second plurality of complex multipliers includes substantially [mathematical expression included] additional inputs. |
| Claim: | 19. The analog precoder chip of claim 15 , wherein the at least one coefficient input configured to receive: precoder coefficients in addition to the pre-distortion coefficients. |
| Claim: | 20. The analog precoder chip of claim 19 , wherein the precoder coefficients are at least partially calculated in a baseband chip and passed to the analog precoder chip. |
| Patent References Cited: | 8565345 October 2013 Gupta 2011/0235748 September 2011 Kenington |
| Primary Examiner: | Panwalkar, Vineeta |
| Attorney, Agent or Firm: | McAndrews, Held & Malloy, Ltd. |
| Přístupové číslo: | edspgr.09762302 |
| Databáze: | USPTO Patent Grants |
| Abstrakt: | A 5G base station transmitter at least partially precodes data for beam forming, and generates digital precoded baseband signals. Cross product circuitry coupled to the digital precoder, generates digital cross products of the digital precoded baseband signals. Both the baseband signals and the cross products are put through digital-to-analog converters (DACs), then provided to an analog non-linear precoder. The analog non-linear precoder combines the analog baseband signals, the cross products, with pre-distortion and precoder coefficients to generate a signal that is pre-compensated for power amplifier non-linearity. The pre-compensated signal is amplified by the power amplifier and transmitted via a phased antenna array. The number of extra DACs required for inserting pre-distortion when a hybrid digital/analog precoder is used can be limited to approximately [mathematical expression included] where NRF is the number of outputs of the digital precoder. This is significantly fewer than the number of extra DACs used by other methods. |
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