DEVICE AND METHOD FOR PROCESSING DIGITAL SIGNALS

Abstract

The present invention provides a device for processing digital signals. The device comprises a digital signal source and a converter circuit having a current supply. The digital signal source outputs a codeword. The converter circuit receives the codeword from the digital signal source, receives a current at the current supply, and generates an output signal based on the codeword. The device generates the current based on the codeword.

Claims

1. A device for processing digital signals, comprising: a digital signal source configured to output a codeword; and a converter circuit having a current supply, the converter circuit being configured to: receive the codeword from the digital signal source, receive a current at the current supply, and generate an output signal based on the codeword; wherein the device is configured to generate the current based on the codeword.

2. The device according to claim 1, wherein the device is configured to generate the current in accordance with a required current draw.

3. The device according to claim 2, wherein the required current draw is a time-varying current that the converter circuit must consume to generate the output signal based on the codeword.

4. The device according to claim 3, configured to generate the current, based on the codeword, such that the current at least matches the required current draw.

5. The device according to claim 1, configured to generate the current additionally based on a configuration of the converter circuit.

6. The device according to claim 5, wherein the configuration of the converter circuit includes a number of cells that contribute to the generation, by the converter circuit, of the output signal based on the codeword.

7. The device according to claim 1, wherein the converter circuit includes a digital-to-analog converter (DAC), and wherein a current supply of the DAC is configured to receive the current.

8. The device according to claim 1, comprising a feed forward circuit connected to the digital signal source and configured to generate the current.

9. The device according to claim 8, wherein the feed forward circuit includes a DAC.

10. The device according to claim 9, wherein the feed forward circuit further includes a bias generation section connected to the DAC, wherein the bias generation section comprises a mirroring device configured to mirror an operation of the DAC, and wherein the mirroring device includes a feedback circuit.

11. The device according to claim 8, wherein the codeword is a first codeword, the digital signal source is configured to output a second codeword based on the first codeword, and the feed forward circuit is configured to receive the second codeword from the digital signal source and generate the current based on the second codeword.

12. The device according to claim 1, further comprising a power supply configured to provide a DC output voltage to the current supply of the converter circuit.

13. The device according to claim 12, configured such that the current received at the current supply of the converter circuit together with an output current generated by the power supply exceeds a required current draw.

14. The device according to claim 13, configured to perform a pre-distortion of the output signal generated by the converter circuit.

15. The device according to claim 12, wherein the power supply includes a voltage regulator.

16. A method for processing digital signals, the method comprising: providing, by a digital signal source, a codeword to a converter circuit, generating a current based on the codeword, receiving, by the converter circuit at a current supply of the converter circuit, the current, and generating, by the converter circuit, an output signal based on the codeword.

17. The method according to claim 16, wherein generating the current based on the codeword comprises: generating the current based on the codeword in accordance with a required current draw.

18. The device according to claim 17, wherein the required current draw is a time-varying current that the converter circuit must consume to generate the output signal based on the codeword.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0055] The above described aspects and implementation forms will be explained in the following description of specific embodiments in relation to the enclosed drawings, in which

[0056] FIG. 1 shows a device according to an embodiment.

[0057] FIG. 2 shows a device according to an embodiment using two DACs.

[0058] FIG. 3 shows a device according to an embodiment using two DACs.

[0059] FIG. 4 shows a feed forward circuit of a device according to an embodiment including a DAC and a bias generation section for biasing the DAC.

[0060] FIG. 5 shows a feed forward circuit of a device according to an embodiment including a DAC and a bias generation section for biasing the DAC.

[0061] FIG. 6 shows a method according to an embodiment.

[0062] FIG. 7 shows results of simulating the harmonic distortion of the converter circuit of a device according to an embodiment.

DETAILED DESCRIPTION OF EMBODIMENTS

[0063] FIG. 1 shows a device 100 according to an embodiment. The device 100 is configured to process digital signals. The device 100 comprises a digital signal source 101, a converter circuit 102, and a feed forward circuit 105.

[0064] The digital signal source 101 is configured to output codewords of a digital signal, for instance, at least one first codeword 104 and at least one second codeword 107. The at least one first codeword 104 is supplied to the converter circuit 102, while the at least one second codeword 107 is supplied to the feed forward circuit 105. The digital signal source 101 may specifically be configured to supply multiple (different) first codewords 104 to the converter circuit 102 in a consecutive manner, e.g. changing codewords of a digital signal. At the same times it may supply multiple (different) second codewords 107—one for each first codeword 104—to the feed forward circuit 105.

[0065] The converter circuit 102 is configured to generate an output signal 103 based on the at least one first codeword 104 received from the digital signal source 101. Thus, it can convert a digital signal into an analog signal. The feed forward circuit 105 is configured to generate an output current 106 based on the at least one second codeword 107 received from the digital signal source 101.

[0066] This output current 106 of the feed forward circuit 105 is advantageously connected (directly or indirectly) to a current supply 108 of the converter circuit 102. Moreover, the digital signal source 101 is configured to generate the at least one second codeword 107 based on the at least one first codeword 104. Thereby, the digital signal source 101 is able to compensate variations of a supply current of the converter circuit 105.

[0067] In an implementation, the digital signal source 101 is configured to generate the at least one second codeword 107, so as to reduce supply voltage variations to which the performance of the converter circuit 105 is sensitive. Thereby, the digital signal source 101 is configured to generate the second codeword 107 based on a current consumption of the converter circuit 105 when generating the output signal 103 based on the first codeword 104. The digital signal source 101 has knowledge of this codeword-dependent current consumption of the converter circuit 102, and can select the second codeword 107 accordingly. The digital signal source 101 may generate the second codeword 107 such that the output current 103 of the feed forward circuit 105 at least matches a current required by the converter circuit 102 for generating the output signal 103 based on the first codeword 104. Notably, over-compensating of the current required by the converter circuit 102 is also possible.

[0068] In the following, the above-described concept is further illustrated for the case of a DAC, where the impact is on both the digital and analog subsystem. However, the invention is notably not limited to a DAC.

[0069] FIG. 2 shows a device 100 according to an embodiment, which builds on the device 100 shown in FIG. 1. Same elements are labelled with same reference signs and function likewise. Accordingly, also the device 100 of FIG. 2 has the digital signal source 101 for providing the first and second codewords 104 and 107, respectively, the converter circuit 102 for outputting the output signal 103 based on the first codeword 104, and the feed forward circuit 105 for supplying the output current 106 produced based on the second codeword 107 towards the converter circuit 102.

[0070] FIG. 2 illustrates specifically a device 100, in which the converter circuit 102 is (or includes) a first DAC 202, in which the feed forward circuit 105 is (or includes) a second DAC 205, and in which the output current 106 of the feed forward circuit 105 is provided to a current supply 108 of the first DAC 202. Because the supply current I.sub.supply required by the first DAC 202 is (indirectly) known to the digital signal source 101, an open loop correction can be performed with the second DAC 205.

[0071] FIG. 2 shows in detail that the digital signal source 101 is a digital system including at least one data source 200. The digital signal source 101 is configured to output the first codeword 104, in order to set the output level of the first DAC 202. This causes the first DAC 202 to consume a certain amount of current related to the first codeword 104. At the same time, however, the digital signal source 101 is configured to program the second DAC 205 with a second (correction) codeword 107, thereby setting its output current 106 (I.sub.corr). When this resulting output current 106 matches the current required by the first DAC 202, only a very small current (I.sub.LDO) would be drawn from a supply unit 201 (e.g. an LDO). The supply unit 201 may be part of the device 100 or not. As a result, voltage variations of the supply of the first DAC 202 are very strongly suppressed—if not eliminated. The second codeword 107 can be calculated from the first codeword 104, for instance taking into account the structure of the first DAC 202 (e.g. the construction of the first DAC 202 from current switching cells with unit weight or binary scaled weights).

[0072] The above-described current injection concept can also be applied to blocks of a device 100 other than the first DAC 202, as long as the current consumption profile of the block can be predicted.

[0073] FIG. 3 shows in this respect an exemplary device 100, which builds on the device 100 shown in FIG. 1 and has several components in common with the device 100 shown in FIG. 2. Same elements are labelled with same reference signs and function likewise. Accordingly, also the device 100 of FIG. 3 has the digital signal source 101 for providing the first and second codewords 104 and 107, the converter circuit 102 for outputting the output signal 103 based on the first codeword 104, and the feed forward circuit 105 for supplying the output current 106 based on the second codeword 107 towards the converter circuit 102.

[0074] FIG. 3 illustrates specifically a device 100, in which the converter circuit 102 includes a first DAC 202 connected in series with a power amplifier 300 (as example of another block to which the current injection concept can be applied). Further, the feed forward circuit 105 is (or includes) a second DAC 202. The output current 106 of the feed forward circuit 105, which bases on the second codeword 107, is in this device 100 provided to a current supply of the power amplifier 300 (not of the first DAC 202 as in FIG. 2). Accordingly, the current injection concept is here used to reduce a supply ripple and distortion of the power amplifier 300, because this is correlated with the first codeword 104, and the second codeword 107 is generated on the second codeword 107 to compensate variations of a supply current of the power amplifier 300 of the converter circuit 102.

[0075] The converter circuit 105 may further include a bandpass filter 300. In particular, the first DAC 202 may be followed by the bandpass filter 301 and then the power amplifier 300, i.e. the bandpass filter 301 may be connected in series between the first DAC 202 and the power amplifier 300.

[0076] FIG. 3 shows in detail that the first codeword 104 from the digital signal source 101 is converted to an analog signal by the first DAC 102 (which is e.g. directly supplied by a supply unit, which may be an LDO, without any correction). The first DAC 202 drives the power amplifier 300. The current consumption of the power amplifier 300 depends on its input signal (i.e. on the codeword-dependent output signal of the first DAC 202) and will cause distortion. If, however, the second DAC 205 is connected, as in FIG. 3, in parallel with a supply unit 201 of the power amplifier 300, a supply ripple can be reduced. To this end, the second codeword 107 is specifically generated so as to compensate variations of a supply current of the power amplifier 300, which variations are caused indirectly by the first codeword 104. That is, knowledge of a current consumption required by the power amplifier 300 specifically for amplifying the output of the DAC 102 based on the first codeword 104 is used to generate the second codeword for the second DAC 205, in order to counter a supply ripple at the power amplifier 300. Thereby, the second codeword 107 generated for the second DAC 205 can, for example, be obtained from a one-time characterization of the device 100 or can be obtained from a calibration loop. Depending on the kind of non-linearities in the power amplifier 300, it is possible that this type of correction is less computationally intensive than a conventional digital pre-distortion solution.

[0077] In the devices 100 of FIG. 2 and FIG. 3, respectively, it is also possible to overcompensate by injecting more current than required by the first DAC 202. This may further reduce harmonic distortion. In effect, by overcompensating, a pre-distorting of the first DAC 202 in the analog domain is carried out.

[0078] In an embodiment, only information regarding the current consumption of the first DAC 202 may be used when generating the second codeword 107 based on the first codeword 104, in order to compensate variations of a supply current of the second DAC 202. However, it is also possible that other information can be derived from the first codeword 104. Thus, it is also possible to reduce—in the same manner—other spurs present in the device 100 (e.g. LO leakage), using the second DAC 205.

[0079] The scale of the second DAC 205 may be programmable. This enables fine-tuning the required current of the first DAC 202 over process, voltage, temperature or other variations (PVT variations). The power consumption may also depend on the operation frequency of the first DAC 202, which can also be taken into account when changing the scale of the second DAC 205.

[0080] FIG. 4 shows an exemplary implementation of a feed forward circuit 105 for a device 100 according to an embodiment, e.g. a device 100 as shown in the FIGS. 1-3. This feed forward circuit 105 is specifically implemented for the case of a 10-bit radio frequency DAC (RFDAC) as the first DAC 202. The RFDAC consisted of 64 cells, which are used in pairs of two. Thus, a 5-bit second DAC 205 may be used in the feed forward circuit 105. The current switching cells 400 of this second DAC 205 may include p-type metal oxide semiconductor (PMOS) devices, and are for switching a main supply current to an output (correction) current 106 provided towards the first DAC 202. FIG. 4 shows specifically that the second DAC 205 is implemented as a current DAC and is biased from a bias generation section 401 using a diode connected PMOS device 402.

[0081] While the feed forward circuit 105 of FIG. 4 allows compensating codeword-dependent supply variations of the first DAC 202, and thus improving the performance of the device 100, it is not yet optimized for PVT variations. In particular, in this exemplary implementation the drain voltage of the second DAC 205 (“vdd_dac”) can vary from the drain voltage of the diode device 402 in the bias generation section 401. Because of this, the amount of injected current could potentially vary over PVT variations. This would entail that during operation of the device 100, one would need to adjust the bias point. And such adjustments would require inputs such as operating voltages, temperature, etc.

[0082] The settings of the second DAC 205 can be made independent of PVT variations as presented in the following. The presented solution notably could presents also a strong improvement on other bias strategies. In particular, the feed forward circuit 105 may include a mirroring device 501 its bias generation section 401 connected to the second DAC 205—as shown in FIG. 5.

[0083] FIG. 5 shows again a feed forward circuit 105 of a device 100 according to an embodiment, e.g. a device 100 as shown in the FIGS. 1-3. The exemplary feed forward circuit 105 particularly builds on the one shown in FIG. 4.

[0084] FIG. 5 shows specifically that the mirroring device 501 includes the diode device 402 and a feedback circuit. When the reference voltage “vref” tracks the DAC supply voltage “vdd_dac”, a bias feedback loop can make the current per cell 400 of the second DAC 205 independent of PVT variations. This is because the reference PMOS device is then operating under identical conditions as the second DAC cells 400. The output current 106 is then also independent of the operating region of the feed forward circuit 105. Key is that the mirroring device 501 operates under identical conditions as the cells 400 of the secondary DAC 205. The mirroring device 501 is exemplarily implemented using a feedback circuit, but there are other ways of accomplishing it. For example, by making use of a cascode transistor.

[0085] An alternative to the bias feedback loop could be a voltage DAC to set in FIG. 4 the “vref_pmos” voltage. However, this would suffer from the drawback that this reference voltage needs to be adjusted over VT corners, i.e. during operation of the device 100.

[0086] FIG. 6 shows a method according to an embodiment. The method 600 can be carried out for processing digital signals. For instance, the method 100 may be performed by a device 100 according to an embodiment of the present invention as shown FIGS. 1-5.

[0087] The method 600 includes a step 601 of providing, by a digital signal source 101, a first codeword 104 to a converter circuit 102, in order to generate an output signal 103. Further, the method 600 comprises a step 602 of providing, by the digital signal source 101, a second codeword 107 to a feed forward circuit 105, in order to generate an output current 106. The output current 106 of the feed forward circuit 105 is supplied to the converter circuit 102. Further, the second codeword 107 is generated by the digital signal source 101 based on the first codeword 104, particularly such that variations of a supply current of the converter circuit 102 are compensated.

[0088] FIG. 7 shows simulations performed on the dynamic performance of the first DAC 202 of a device 100 according to an embodiment, while changing the scale (x-axis) of the second DAC 205. In particular, in the top graph results 702 and 703 on the harmonic distortion (in dB) of the first DAC 202 are shown. The simulation result 702 is obtained at a different operating frequency than the simulation result 703. The bottom graph shows results 700 and 701 of the corresponding supply variation of the first DAC 202 (in dB). Again, the result 700 is obtained at a different operating frequency than the result 701. The arrows between the top and bottom graph show that the result 702 corresponds to the result 701, and the result 703 corresponds to the result 700.

[0089] In particular, the largest (frequency-dependent) non-linearity/harmonic distortion (top graph) and the largest supply ripple/variation (bottom graph) are illustrated in FIG. 7 as a function of the scale of the second DAC 205. It can be seen that the scale at which the supply ripple is minimal does not correspond to the scale of lowest harmonic distortion. This entails that the present invention allows doing even better than simply reducing a supply ripple, but also performing an analog pre-distortion. At the same time, the input codeword 107 applied to the second DAC 205 is directly proportional to the input codeword 104 of the first DAC 202, leading to very little overhead in the digital data source 101 (as opposed to digital pre-distortion).

[0090] The present invention has been described in conjunction with various embodiments as examples as well as implementations. However, other variations can be understood and effected by those persons skilled in the art and practicing the claimed invention, from the studies of the drawings, this disclosure and the independent claims. In the claims as well as in the description the word “comprising” does not exclude other elements or steps and the indefinite article “a” or “an” does not exclude a plurality. A single element or other unit may fulfill the functions of several entities or items recited in the claims. The mere fact that certain measures are recited in the mutual different dependent claims does not indicate that a combination of these measures cannot be used in an advantageous implementation.