An encoder includes a state machine configured to generate a payloads as a function of a state machine output, and an interface configured to generate a tail as a function of a binary representation of the state machine output at the end of the payload generation. It is emphasized that this abstract
An encoder includes a state machine configured to generate a payloads as a function of a state machine output, and an interface configured to generate a tail as a function of a binary representation of the state machine output at the end of the payload generation. It is emphasized that this abstract is provided to comply with the rules requiring an abstract which will allow a searcher or other reader to quickly ascertain the subject matter of the technical disclosure. It is submitted with the understanding that it will not be used to interpret or limit the scope or the meaning of the claims.
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What is claimed is: 1. An encoder, comprising: a state machine configured to generate a plurality of state bits, and an interface configured to couple an input relating to one of the state bits into the state machine during a time period, wherein the interface is configured to couple an input signa
What is claimed is: 1. An encoder, comprising: a state machine configured to generate a plurality of state bits, and an interface configured to couple an input relating to one of the state bits into the state machine during a time period, wherein the interface is configured to couple an input signal into the state machine during a second time period, and couple a complement of said one of the state bits into the state machine during the time period. 2. An encoder, comprising: state generation means for generating a plurality of state bits, and interface means for coupling an input relating to one of the state bits into the state generation means during a time period, wherein the interface means is configured to couple an input signal into the state generation means during a second time period, and couple a complement of said one of the state bits into the state generation means during the time period. 3. A transmitter, comprising: an encoder comprising: a state machine configured to generate a plurality of state bits, and an interface configured to couple an input relating to one of the state bits into the state machine during a time period; and an RF stage coupled to the encoder; wherein the RF stage and the encoder are each an integral part of the transmitter and wherein the interface is configured to couple an input signal into the state machine during a second time period, and couple a complement of said one of the state bits into the state machine during the time period. 4. A transmitter, comprising: an encoder comprising: state generation means for generating a plurality of state bits, and interface means for coupling an input relating to one of the state bits into the state generation means during a time period; and an RF stage coupled to the encoder; wherein the RF stage and the encoder are each an integral part of the transmitter and wherein the interface means is configured to couple an input signal into the state generation means during a second time period, and couple a complement of said one of the state bits into the state generation means during the time period. 5. An encoder, comprising: a state machine configured to generate a state, and an interface configured to serially couple an input relating to a binary representation of the state into the state machine during a time period, wherein the interface is configured to serially couple a plurality of input signals into the state machine during a second time period, and serially couple a complement of the binary representation of the state at the end of the second period into the state machine during the time period. 6. An encoder, comprising: state generation means for generating a state, and interface means for serially coupling an input relating to a binary representation of the state into the state machine during a time period, wherein the interface means comprises a switching circuit configured to serially couple input signals into the state generation means during the second time period, and serially couple a complement of the binary representation of the state at the end of the second period into the state generation means during the time period. 7. A method of generating a signal, comprising: generating a payload as a function of a state machine output; generating a tail as a function of a binary representation of the state machine output at the end of the payload generation, and appending the tail to the payload, wherein the state machine output comprises a plurality of state bits, the tail generation comprising serially feeding a complement of each of the state bits for the binary representation of the state machine output at the end of the payload generation into the state machine. 8. A method of generating a signal, comprising: generating a payload as a function of a state machine output, generating a tail as a function of a binary representation of the state machine output at the end of the payload generation, and appending the tail to the payload, wherein the state machine output comprises a plurality of first state bits having a most significant bit, the tail generation comprising feeding the most significant bit of the first state bits into the state machine during a first clock cycle to generate a plurality of second state bits having a most significant bit, and feeding the most significant bit of the second state bits into the state machine during a second clock cycle. 9. The method of claim 8 wherein the first state bits further comprise a least significant bit, and wherein the most significant bit of the second state bits is the least significant bit of the first state bits. 10. A method of generating a signal, comprising: generating a payload as function of a state machine output, generating a tail as a function of a binary representation of the state machine output at the end of the payload generation, and appending the tail to the payload, wherein the state machine output comprises a plurality of first state bits having a most significant bit, the tail generation comprising feeding a complement of the most significant bit of the first state bits into the state machine during a first clock cycle to generate a plurality of second state bits having a most significant bit, and feeding a complement of the most significant bit of the second state bits into the state machine during a second clock cycle. 11. The method of claim 10, wherein the first state bits further comprise a least significant bit, and wherein the most significant bit of the second state bits is the least significant bit of the first state bits. 12. The encoder of claim 1, wherein the interface comprises a switching circuit. 13. The encoder of claim 1, further comprising an output including a second one of the state bits. 14. The encoder of claim 13, wherein the interface comprises an output, the encoder output further including the interface output. 15. The encoder of claim 1, wherein the state machine comprises a 2p-state finite state machine where P comprises an integer greater than one. 16. The encoder of claim 1, wherein the state machine comprises at least two delay registers configured to delay the plurality of state bits. 17. The encoder of claim 16, wherein the state machine comprises an adder coupled to at least one of the delay registers. 18. The encoder of claim 2, wherein the interface means comprises a switching circuit. 19. The encoder of claim 2, further comprising an output including a second one of the state bits. 20. The encoder of claim 19, wherein the interface means comprises an output, the encoder output further including the interface means output. 21. The encoder of claim 2, wherein the state generation means comprises a 2P-state finite state machine where P is an integer greater than one. 22. The encoder of claim 2, wherein the state generation means comprises at least two delay registers configured to delay the plurality of state bits. 23. The encoder of claim 22, wherein the state generation means comprises an adder coupled to at least one of the delay registers. 24. The transmitter of claim 3, wherein the interface comprises a switching circuit. 25. The transmitter of claim 3, wherein the encoder further comprises an output including a second one of the state bits. 26. The transmitter of claim 25, wherein the interface comprises an output, the encoder output further including the interface output. 27. The transmitter of claim 3, wherein the state machine comprises a 2p-state finite state machine where P comprises an integer greater than one. 28. The transmitter of claim 3, wherein the state machine comprises at least two delay registers configured to delay the plurality of state bits. 29. The transmitter of claim 28, wherein the state machine comprises an adder coupled to at least one of the delay registers. 30. The transmitter of claim 4, wherein the interface means comprises a switching circuit. 31. The transmitter of claim 4, wherein the encoder further comprises an output including a second one of the state bits. 32. The transmitter of claim 31, wherein the interface means comprises an output, the encoder output further including the interface means output. 33. The transmitter of claim 4, wherein the state generation means comprises a 2P-state finite state machine where P is an integer greater than one. 34. The transmitter of claim 4, wherein the state generation means comprises at least two delay registers configured to delay the plurality of state bits. 35. The transmitter of claim 34, wherein the state generation means comprises an adder coupled to at least one of the delay registers. 36. The encoder of claim 5, wherein the state machine comprises a 2P-state finite state machine where P comprises an integer greater than one. 37. The encoder of claim 5, wherein the state machine comprises at least two delay registers configured to generate the state. 38. The encoder of claim 37, wherein the state machine comprises an adder coupled to at least one of the delay registers. 39. The encoder of claim 6, wherein the state generation means comprises a 2P-state finite state machine where P comprises an integer greater than one. 40. The encoder of claim 6, wherein the state generation means comprises at least two delay registers configured to generate the state. 41. The encoder of claim 40, wherein the state generation means comprises an adder coupled to at least one of the delay registers. 42. An encoder comprising: a state machine configured to generate a plurality of state bits comprising a most significant bit and a second bit different from the most significant bit; and an interface comprising at least one switching circuit and configured to couple an input representative of the most significant bit into the state machine during a time period and to couple a second input representative of the second bit into the state machine during a time period. 43. The method of claim 8, wherein: generating a payload comprises providing data bits to the state machine through a switching circuit; and generating a tail comprises providing state bits to the state machine through the switching circuit. 44. The method of claim 8, wherein generating a tail comprises adding a least significant bit of the first state bits to the tail during the first clock cycle, and adding a least significant bit of the second state bits to the tail during the second clock cycle. 45. The method of claim 8, wherein the state machine comprises a 2P-state finite state machine where P comprises an integer greater than one. 46. The method of claim 8, wherein the state machine comprises at least two delay registers configured to delay the plurality of first state bits. 47. The method of claim 46, wherein the state machine comprises an adder coupled to at least one of the delay registers. 48. The method of claim 10, wherein: generating a payload comprises providing data bits to the state machine through a switching circuit; and generating a tail comprises providing complement state bits to the state machine through the switching circuit. 49. The method of claim 10, wherein generating a tail comprises adding a least significant bit of the first state bits to the tail during the first clock cycle, and adding a least significant bit of the second state bits to the tail during the second clock cycle. 50. The method of claim 10, wherein the state machine comprises a 2P-state finite state machine where P comprises an integer greater than one. 51. The method of claim 10, wherein the state machine comprises at least two delay registers configured to delay the plurality of first state bits. 52. The method of claim 51, wherein the state machine comprises an adder coupled to at least one of the delay registers. 53. The encoder of claim 42, wherein the interface is configured to couple an input representative of the most significant bit into the state machine during a first time period, and couple a second input representative of the second bit into the state machine during a second time period different from the first time period. 54. The encoder of claim 42, wherein: the interface is configured to couple an input representative of the most significant bit into the state machine during a first time period; and the encoder comprises an output configured to output a bit representative of a state bit other than the most significant bit during the first time period. 55. The encoder of claim 42, wherein the period during which the second input representative of the second bit is coupled into the state machine is subsequent to the time period during which the input representative of the most significant bit is coupled into the state machine. 56. The encoder of claim 42, wherein the state machine comprises a 2P-state finite state machine where P comprises an integer greater than one. 57. The encoder of claim 42, wherein the state machine comprises at least two delay registers configured to delay the plurality of state bits. 58. The encoder of claim 57, wherein the state machine comprises an adder coupled to at least one of the delay registers. 59. The encoder of claim 42, wherein the time period during which the second input representative of the second bit is coupled into the state machine is adjacent to the time period during which the input representative of the most significant bit is coupled into the state machine. 60. An encoder comprising: a state machine configured to generate a plurality of state bits comprising a most significant bit and a second bit different from the most significant bit; and an interface configured to couple an input representative of the most significant bit into the state machine during a first time period, and couple a second input representative of the second bit into the state machine during a second time period different from the first time period. 61. The encoder of claim 60, wherein the interface comprises at least one switching circuit through which data bits and state bits are provided to the state machine. 62. The encoder of claim 60, wherein the second time period is subsequent to the first time period. 63. The encoder of claim 60, wherein the second time period and the first time period are adjacent to each other. 64. The encoder of claim 60, wherein the state machine comprises a 2P-state finite state machine where P comprises an integer greater than one. 65. The encoder of claim 60, wherein the state machine comprises at least two delay registers configured to delay the plurality of state bits. 66. The encoder of claim 65, wherein the state machine comprises an adder coupled to at least one of the delay registers.
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