Digital-to-analog converter with improved linearity

What is claimed is: 1. A digital-to-analog converter (DAC) circuit to reduce gain mismatch errors and including an input to receive a stream of digital input words, each digital input word partitioned into a most significant bit (MSB) digital subword and a least significant bit (LSB) digital subword, the circuit comprising: a digital noise shaper circuit to receive a representation of the LSB subword, the digital noise shaper configured to output a modulated LSB subword; an LSB DAC circuit to receive and convert a combination of a representation of the LSB subword and the modulated LSB subword and to generate a first analog output; an MSB DAC circuit to receive and convert a combination of a representation of the MSB digital subword and the modulated LSB subword and to generate a second analog output, wherein each of the first analog output and the second analog output are combined to produce an analog output that represents the stream of digital input words. 2. The DAC circuit of claim 1 , the circuit comprising: a segmentation circuit including an input to receive the stream of digital input words, the segmentation circuit comprising: the digital noise shaper circuit; an LSB circuit to receive the LSB digital subword and the modulated LSB subword, the LSB circuit to combine the modulated LSB subword and the corresponding LSB digital subword to generate a first digital output; an MSB circuit to receive the MSB digital subword and the modulated LSB subword, the MSB circuit to combine the modulated LSB subword and the MSB digital subword to generate a second digital output. 3. The DAC circuit of claim 1 , wherein the digital noise shaper circuit includes a delta-sigma modulator circuit. 4. The DAC circuit of claim 3 , wherein the digital noise shaper circuit includes a delaying integrator circuit, and wherein the modulated LSB subword received by the LSB circuit is a complement of the modulated LSB subword received by the MSB circuit. 5. The DAC circuit of claim 2 , wherein the digital noise shaper circuit is coupled to an output of the LSB circuit. 6. The DAC circuit of claim 2 , wherein the digital noise shaper circuit is coupled to an input of the LSB circuit. 7. The DAC circuit of claim 6 , further comprising: an MSB delay circuit coupled to an input of the MSB circuit to receive and delay the MSB digital subword; and an LSB delay circuit coupled to an input of the LSB circuit to receive and delay the LSB digital subword. 8. The DAC circuit of claim 2 , wherein the digital noise shaper circuit includes a delta-sigma modulator circuit having an error feedback configuration, and wherein the delta-sigma modulator circuit is coupled to an input of the LSB circuit. 9. The DAC circuit of claim 2 , wherein the stream of digital input words further includes a sub-LSB digital subword, the segmentation circuit further comprising: a sub-LSB digital noise shaper circuit having an input to receive a representation of the sub-LSB subword, the sub-LSB digital noise shaper configured to output a modulated sub-LSB subword; a sub-LSB circuit to receive the sub-LSB digital subword and the modulated sub-LSB subword, the sub-LSB circuit to subtract the modulated sub-LSB subword from the corresponding sub-LSB digital subword to generate a third digital output; and a sub-LSB DAC circuit to receive and convert a representation of the third digital output and to generate a third analog output. 10. The DAC circuit of claim 1 , wherein the digital noise shaper circuit includes a dual register circuit having a first register and a second register, wherein the first register and the second register are randomly selected. 11. The DAC circuit of claim 1 , wherein the digital noise shaper circuit includes a plurality of code-selected registers. 12. The DAC circuit of claim 1 , further comprising: a dither generator circuit configured to provide different dither values to the digital noise shaper circuit. 13. A method of operating a digital-to-analog converter circuit to reduce gain mismatch errors, the method comprising: receiving a stream of digital input words, each digital input word partitioned into a most significant bit (MSB) digital subword and a least significant bit (LSB) digital subword; noise shaping a representation of the LSB subword to generate a modulated LSB subword; receiving and converting a combination of a representation of the LSB subword and the modulated LSB subword and generating a first analog output; receiving and converting a combination of a representation of the MSB digital subword and the modulated LSB subword and generating a second analog output; and combining each of the first analog output and the second analog output to produce an analog output that represents the stream of digital input words. 14. The method of claim 13 , the method further comprising: receiving, using an LSB circuit, the LSB digital subword and the modulated LSB subword, and combining the modulated LSB subword and the corresponding LSB digital subword to generate a first digital output; receiving, using an MSB circuit, the MSB digital subword and the modulated LSB subword, and combining the modulated LSB subword and the MSB digital subword to generate a second digital output. 15. The method of claim 13 , wherein noise shaping a representation of the LSB subword to generate a modulated LSB subword includes using a delta-sigma modulator circuit to noise shape the representation of the LSB subword to generate the modulated LSB subword. 16. The method of claim 13 , wherein the noise shaping includes using a delaying integrator circuit. 17. The method of claim 14 , further comprising: coupling a noise shaping circuit to an output of the LSB circuit. 18. The method of claim 14 , further comprising: coupling a noise shaping circuit to an input of the LSB circuit. 19. The method of claim 18 , further comprising: coupling an MSB delay circuit to an input of the MSB circuit to receive and delay the MSB digital subword; and coupling an LSB delay circuit to an input of the LSB circuit to receive and delay the LSB digital subword. 20. The method of claim 14 , wherein noise shaping a representation of the LSB subword to generate a modulated LSB subword includes using a delta-sigma modulator circuit having an error feedback configuration to noise shape the representation of the LSB subword to generate the modulated LSB subword, the method further comprising: coupling the delta-sigma modulator circuit to an input of the LSB circuit. 21. An integrated circuit device comprising: an analog-to-digital converter circuit including a digital-to-analog converter (DAC) circuit, the DAC circuit comprising: a segmentation circuit including an input to receive a stream of digital input words, each digital input word including a MSB digital subword and an LSB digital subword, the segmentation circuit comprising: a digital noise shaper circuit having an input to receive a representation of the LSB subword, the digital noise shaper configured to output a modulated LSB subword, wherein the modulated LSB subword has a smaller word length than the LSB subword; an LSB circuit to receive the LSB digital subword and the modulated LSB subword, the LSB circuit to subtract the modulated LSB subword from the corresponding LSB digital subword to generate a first digital output, the LSB circuit including an LSB encoder circuit; an MSB circuit to receive the MSB digital subword and the modulated LSB subword, the MSB circui