The present invention relates to a signal converter, and more particularly to a digital-to-analog converter (DAC) and a performing method thereof.
Nowadays, DACs are required for converting digital signals to analog signals in various electronic products, such as communication systems. Current calibration and dynamic element matching (DEM) are the most commonly used for low-cost design. In the Institute of Electrical and Electronics Engineers (IEEE) published papers, the cost of the DEM technique is lower than that of the current calibration technique. Furthermore, the DEM technique may be applied for various technologies because the DEM encoder is implemented with digital circuits. The current calibration technique is limited for certain technologies because some of its building blocks are implemented with analog circuits.
In the DEM technique, inputs are rotated for generating specific outputs. The DEM technique comprises binary-weighted architectures, thermometer-coded architectures and algorithmic controller embedded architectures. The architectures with algorithmic controllers can be used to decrease the switching occurrence. However, the controller embedded architectures are more complicated which require more implementation cost, and can't be operated. in high-speed applications. The conventional binary-weighted architectures have advantages of low cost, low complexity, and low power consumption. However, when inputs approach the Nyquist frequency, the switching occurrence is greatly increased and which encounters glitch problems and the linearity is therefore affected. Accordingly, the conventional binary-weighted architectures are seldom used. Compared with the conventional binary-weighted architectures, the thermometer-coded architectures have a lower switching occurrence and can reduce noises. However, the thermometer-coded architectures must comprise additional control circuits, and thus the power consumption and the area cost are higher than those of the conventional binary-weighted architectures. Besides, the operation speed is limited.
Therefore, there is a need to propose a solution having both the advantages of the binary-weighted architectures and the thermometer-coded architectures without the disadvantages of theirs.
An objective of the present invention is to provide a digital-to-analog converter and a performing method thereof.
According to an aspect of the present invention, the digital-to-analog converter comprises a random rotation unit, a plurality of conversion units, and a summing unit. The random rotation unit receives a plurality of binary-weighted inputs and generates a plurality of rotated digital outputs according to a random rotation number. The conversion units respectively receive one of the rotated digital outputs and generate a respective analog output. The summing unit sums the respective analog outputs of the conversion units for generating an analog output.
According to another aspect of the present invention, in the performing method of the digital-to-analog converter, the digital-to-analog converter comprises a random rotation unit, a plurality of conversion units, and a summing unit. The performing method of the digital-to-analog converter comprises: the random rotation unit receives a plurality of binary-weighted inputs and generates a plurality of rotated digital outputs according to a random rotation number; the conversion units respectively receive one of the rotated digital outputs and generate a respective analog output; and the summing unit sums the respective analog outputs of the conversion units to generate an analog output.
The digital-to-analog converter and the performing method thereof according to the present invention implements the dynamic element matching technique by randomly rotating the binary-weighted inputs without extra controlling circuits or encoding circuits. As a result, the manufacturing cost of the digital-to-analog converter can be reduced.
The following descriptions for the respective embodiments are specific embodiments capable of being implemented for illustrations of the present invention with referring to appended figures.
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The random rotation unit 10 receives a plurality of binary weighted inputs B2˜B0 and generates a plurality of rotated digital outputs W7˜W1 according to a random rotation number. Specifically, the random rotation unit 10 comprises a pseudo-random number generator (PRNG) 100 and a rotator 102. The pseudo-random number generator 100 is utilized for generating the random rotation number. The rotator 102 shifts and rotates the binary weighted inputs B2˜B0 according to the random rotation number for generating the rotated digital outputs W7˜W1.
The conversion units U7˜U1 respectively receive one of the rotated digital outputs W7˜W1 and generate one of respective analog outputs Y7˜Y1. Each of the conversion units U7˜U1 may be a current source, a unit capacitor or other suitable elements.
The summing unit 20 sums the respective analog outputs Y7˜Y1 for generating an analog output Yout.
The DAC of the present invention implements the dynamic element matching technique by directly receiving the binary weighted inputs B2˜B0 and randomly rotating the binary weighted inputs B2˜B0. The DAC of the present invention may be regarded as random rotation architecture. Please refer to
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Then, when the binary weighted inputs B2˜B0 are changed from “110” to “011” (i.e. corresponding to 3 in decimal) and the pseudo-random number generator 100 generates the random rotation number having the right-rotation direction and a rotation of 5-steps. The right-rotation of 5-steps is represented as R5 in
When the binary weighted inputs B2˜B0 are changed from “011” to “111” (i.e. corresponding to 7 in decimal) and the pseudo-random number generator 100 generates the random rotation number having the right-rotation of 1-step. The right-rotation of 1-step is represented as R1 in
When the binary weighted inputs B2˜B0 are changed from “111” to “100” (i.e. corresponding to 4 in decimal) and the pseudo-random number generator 100 generates the random rotation number having the right-rotation of 2-steps. The right-rotation of 2-steps is represented as R2 in
Finally, when the binary weighted inputs B2˜B0 are changed from “100” to “101” (i.e. corresponding to 5 in decimal) and the pseudo-random number generator 100 generates the random rotation number having the right-rotation of 0-step. The right-rotation of 0-step is represented as R0 in
It is noted that the
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In a high frequency band, i.e. in the area A1 (about the Nyquist frequency), the average switching rate of the curve C2 is smallest. It means that the conventional thermometer-coded architecture has the best performance. However, extra controlling circuits or encoding circuits are required in the conventional thermometer-coded architecture, so that the required layout area is largest, and the cost and power consumption are highest too. Accordingly, the conventional thermometer-coded architecture is not suitable in high speed portable applications, such as communication systems. Compared with the switching occurrence of the conventional thermometer-coded architecture, the switching occurrence of the random rotation architecture of the present invention (curve C3) in the area Al can be decreased by about 20%. As a result, a glitch problem of the conventional binary-weighted architecture due to the large switching occurrence in the high frequency band can be solved.
In a low frequency band, i.e. in the area A2, the average switching rate of the curve C2 is smallest. It means that the conventional thermometer-coded architecture has the best performance. However, the cost is the highest as mentioned above. Although the performance of the random rotation architecture of the present invention (curve C3) in the area A2 is worse than the performance of the conventional thermometer-coded architecture, the switching occurrence is usually not large in the low frequency band. Accordingly, the effect to low frequency band is limited. In addition, for the purpose of increasing the performance in the low frequency band, the frequency of generating the random rotation number from pseudo-random number generator 100 may be decreased for decreasing the switching occurrence in the low frequency band. Preferredly, the frequency is decreased to ½, ¼, . . . , and so on. The frequency may be set as required.
In summary, the random rotation architecture of the present invention is capable of solving the glitch problem in the high frequency band (i.e. in the area A1) in the conventional binary-weighted architecture. Although the performance of the random rotation architecture of the present invention is worse than the conventional thermometer-coded architecture, the present invention does not required extra controlling circuits or encoding circuits. As a result, the manufacturing (area) cost of the DAC, including digital controlling circuits, analog current switches, and conversion units, can be decreased by more than 80%. The effect of performance degradation of the present invention in the low frequency band (i.e. the area A2) is limited. The random rotation architecture of the present invention is capable of increasing the performance in the low frequency band by decreasing the frequency of generating the random rotation number from the pseudo-random number generator 100.
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The following TABLE 1 shows comparison of the DAC of the random rotation architecture of the present invention, the conventional binary-weighted architecture or the conventional thermometer-coded architecture in International Solid-State Circuit conference (ISSCC) 2011, Transactions on Circuits and Systems I (TCASI) 2010, JSSC 2009, JSSC2006, and JSSC 2001.
In TABLE 1, the area refers to an active area of the DAC. BWN refers to a bandwidth for remaining the SFDR of (6×bit) dB. SFDRDC refers to a best SFDR measured in the Nyquist frequency. SFDRNyquist refers to a worst SFDR measured in the Nyquist frequency. FOM1˜FOM3 refer to figures of merit commonly used in IEEE and define as follows:
It is noted that values of the above-mentioned FOM1˜FOM3 are the higher the better. In comparison with the conventional binary-weighted architecture or the conventional thermometer-coded architecture, the FOM2 and FOM3 of the present invention are better and the FOM1 of the present invention is not bad. As a result, the present invention can implement a high speed DAC with a low area cost.
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In step S820, the conversion units respectively receive one of the rotated digital outputs and generate a respective analog output.
In step S840, the summing unit sums the respective analog outputs of the conversion units to generate an analog output.
In one embodiment, the random rotation unit comprises a pseudo-random number generator and a rotator. Step S800 comprises steps shown in
The present invention has been described with a preferred embodiment thereof and it is understood that many changes and modifications to the described embodiment can be carried out without departing from the scope and the spirit of the invention that is intended to be limited only by the appended claims.
Number | Date | Country | Kind |
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100132605 | Sep 2011 | TW | national |