Apparatus and method for digital beam-forming with low-resolution quantization

The invention claimed is: 1. A power efficient first antenna arrangement configured for digital beam-forming of a transmit signal, the first antenna arrangement comprising; a number N>1 of digital to analog converters (DACs) including a first DAC and a second DAC, each of the N DACs being arranged to receive one respective digital transmit signal component, and to convert and output an analog transmit signal component; and N antenna elements, each of the N antenna elements being coupled to just one of the N DACs such that each of the N antenna elements is configured to receive the analog transmit signal component outputted by the DAC to which the antenna element is coupled, wherein the N antenna elements are further configured to generate a digitally beam-formed transmit signal by having each of the N antenna elements transmit the received analog transmit signal component as part of the digitally beam-formed transmit signal, wherein the first DAC is configured to have a first low resolution such that if the first DAC were used in a second antenna arrangement that utilized only one antenna element to transmit a first analog signal produced by the first DAC, then the first analog signal transmitted by the second antenna arrangement would not fulfill a regulatory radio requirement, the second DAC is configured to have a second low resolution such that if the second DAC were used in a third antenna arrangement that utilized only one antenna element to transmit a second analog signal produced by the second DAC, then the second analog signal transmitted by the third antenna arrangement would not fulfill said regulatory radio requirement, and said digitally beam-formed transmit signal fulfills said regulatory radio requirement. 2. The antenna arrangement according to claim 1 , further comprising a de-correlator arranged to receive N correlated digital transmit signal components, to de-correlate quantization errors in the N correlated digital transmit signal components, and to output the N digital transmit signal components to the respective N DACs. 3. The antenna arrangement according to claim 2 , further comprising a pre-coder arranged to receive a common digital transmit signal vector (TXdig), to pre-code the common digital transmit signal into N correlated digital transmit signal components, and to output N correlated digital transmit signal components to the de-correlator. 4. The antenna arrangement according to claim 2 , wherein the de-correlator comprises N dithering units, each of the N dithering units being configured to receive a respective correlated digital transmit signal component (TX'i), to add a dithering sequence (di) to the received correlated digital transmit signal component, and to output a digital transmit signal component (TXi) based on the added dithering sequence (di) and the received correlated digital transmit signal component (TX'i) to a respective DAC. 5. The antenna arrangement according to claim 4 , wherein one or more of the respective dithering sequences comprises a dithering sequence independent from one or more other dithering sequences of the de-correlator, at least part of the dithering sequences thus being statistically independent of each other. 6. The antenna arrangement according to claim 4 , wherein one or more of the dithering sequences is uniformly distributed over an interval corresponding to −LSB/2 to LSB/2, where LSB denotes a signal amplitude corresponding to the least significant bit of one or more of the N DACs comprised in the antenna arrangement. 7. The antenna arrangement according to claim 4 , wherein one or more of the dithering sequences is distributed according to a normal distribution with zero mean and a pre-determined standard deviation substantially equaling LSB/2, where LSB denotes a signal amplitude corresponding to the least significant bit of one or more of the N DACs comprised in the antenna arrangement. 8. The antenna arrangement according to claim 4 , wherein one or more of the dithering sequences comprises a pseudo-noise, PN, sequence. 9. The antenna arrangement according to claim 4 , wherein one or more of the dithering sequences comprises an additive white Gaussian noise, AWGN, sequence. 10. The antenna arrangement according to claim 4 , wherein one or more of the dithering sequences comprises one out of a number of pre-determined periodic sequences stored in a memory device of the de-correlator. 11. The antenna arrangement according to claim 1 , wherein the regulatory radio requirement comprises one or more requirements on an adjacent channel power ratio (ACPR) of the antenna arrangement. 12. The antenna arrangement according to claim 1 , wherein the regulatory radio requirement corresponds to one or more radio performance requirements defined by third Generation Partnership Project, 3GPP, specification document TS 36.104 V12.3.0. 13. The antenna arrangement according to claim 1 , wherein one or more of the N DACs has a resolution different from one or more other DACs comprised in the antenna arrangement. 14. A network node comprising the antenna arrangement according to claim 1 . 15. A method, performed in a first antenna arrangement, the method comprising; employing N number of digital to analog converters (DACs), wherein N >1, such that each of the N DACs converts a respective digital transmit signal component to produce a respective analog signal component and outputs the respective analog transmit signal component; and using N antenna elements, N>1, to generate a digitally beam-formed transmit signal by having each one of the N antenna elements transmit one of the respective analog transmit signal components as part of the digitally beam-formed transmit signal, wherein the N number of DACs includes a first DAC and a second DAC, the first DAC is configured to have a first low resolution such that if the first DAC were used in a second antenna arrangement that utilized only one antenna element to transmit a first analog signal produced by the first DAC, then the first analog signal transmitted by the second antenna arrangement would not fulfill a regulatory radio requirement, the second DAC is configured to have a second low resolution such that if the second DAC were used in a third antenna arrangement that utilized only one antenna element to transmit a second analog signal produced by the second DAC, then the second analog signal transmitted by the third antenna arrangement would not fulfill said regulatory radio requirement, and said digitally beam-formed transmit signal fulfills said regulator radio requirement. 16. The method according to claim 15 , further comprising; de-correlating quantization errors in N correlated digital transmit signal components to generate the N digital transmit signal components. 17. The method according to claim 16 , the de-correlating further comprising; dithering, by N dithering units, each of the N correlated digital transmit signal components by adding a respective dithering sequence (di) to each correlated digital transmit signal component. 18. The method according to claim 16 , further comprising; pre-coding a common digital transmit signal vector into a number N>1 of correlated digital transmit signal components. 19. A computer program product comprising a non-transitory computer readable medium storing computer program code for performing the method of claim 15 . 20. The first antenna arrangement of claim 1 , wherein the N antenna elements include a first antenna element and a second antenna element, t