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Technology is described herein for encoding and decoding numbers. In one aspect, floating point numbers are represented as binary strings. The binary strings may be encoded in a manner such that if one bit flips, the average and maximum distortion in the number that is represented by the binary stri

Technology is described herein for encoding and decoding numbers. In one aspect, floating point numbers are represented as binary strings. The binary strings may be encoded in a manner such that if one bit flips, the average and maximum distortion in the number that is represented by the binary string is relatively small. In one aspect, 2^n binary strings are ordered across an interval a, b) in accordance with their Hamming weights. Numbers in the interval may be uniformly quantized into one of 2^n sub-intervals. For example, floating point numbers in the interval a, b) may be uniformly quantized into 2^n sub-intervals. These 2^n sub-intervals may be mapped to the 2^n binary strings. Thus, the number may be assigned to one of the 2^n binary strings. Doing so may reduce the distortion in the number in the event that there is a bit flip in the assigned binary string.

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1. An apparatus for encoding numbers into binary form, comprising: a number accesser configured to access representations of numbers stored in non-transitory storage, the numbers being in an interval that comprises 2^n non-overlapping sub-intervals that cover the interval;a quantizer configured to a

1. An apparatus for encoding numbers into binary form, comprising: a number accesser configured to access representations of numbers stored in non-transitory storage, the numbers being in an interval that comprises 2^n non-overlapping sub-intervals that cover the interval;a quantizer configured to assign the respective numbers to one of the 2^n non-overlapping sub-intervals in accordance with a location of the respective number within the interval; anda mapper configured to encode each of the respective numbers as a binary string in non-transitory storage based on the assigned sub-interval, the binary string being one of 2^n binary strings of length “n” that are ordered across the interval in accordance with Hamming distance from a base binary string of length “n”. 2. The apparatus of claim 1, wherein the 2^n binary strings are clustered across the interval in n+1 Hamming groups, wherein each Hamming group comprises only binary strings with the same Hamming distance from the base binary string. 3. The apparatus of claim 2, wherein the interval comprises n+1 non-overlapping sub-intervals that correspond to the n+1 Hamming groups, wherein the mapper is further configured to encode all numbers assigned to a given sub-interval of the n+1 sub-intervals to the Hamming group that corresponds to the given sub-interval. 4. The apparatus of claim 3, wherein, within each of the n+1 Hamming groups, the binary strings are ordered according to binary value, wherein the mapper is further configured to encode the numbers assigned to the given sub-interval in accordance with the binary values of the binary strings in the Hamming group that corresponds to the given sub-interval. 5. The apparatus of claim 1, wherein the mapper is further configured to encode all numbers assigned to a given sub-interval of the 2^n sub-intervals to the same binary string. 6. The apparatus of claim 1, wherein the representations of the numbers are digital representations of floating point numbers. 7. The apparatus of claim 6, wherein to assign respective numbers in the interval to one of 2^n non-overlapping sub-intervals the quantizer is further configured to: uniformly quantize the floating point numbers in the interval into the 2^n sub-intervals. 8. The apparatus of claim 1, further comprising: non-volatile storage;a write circuit configured to store the binary strings that represent the respective numbers in the non-volatile storage; anda demapper configured to decode the stored binary strings with at least one of the binary strings having a bit flipped, wherein the binary string with the bit flipped decodes to a number in the interval other than the number the binary string represented when encoded. 9. The apparatus of claim 1, wherein the base binary string comprises all zeros. 10. A method, comprising: accessing, by a control circuit, digital representations of respective numbers stored in non-transitory storage, the numbers being in an interval that comprises 2^n non-overlapping sub-intervals that cover the interval;assigning, by the control circuit, the respective numbers to one of the 2^n non-overlapping sub-intervals, wherein the assigning is performed in accordance with a location of the respective numbers within the interval;encoding, by the control circuit, each of the respective numbers as a selected binary string of 2^n binary strings that are ordered across the interval by Hamming weight, the encoding being based on the assigned sub-interval; andstoring, by the control circuit, the selected binary strings in non-transitory storage. 11. The method of claim 10, wherein the 2^n binary strings are clustered across the interval in n+1 Hamming groups, wherein each Hamming group comprises only binary strings with the same Hamming weight. 12. The method of claim 11, wherein the interval comprises n+1 non-overlapping sub-intervals that correspond to the n+1 Hamming groups, further comprising: encoding all numbers in a given sub-interval of the n+1 sub-intervals to the Hamming group that corresponds to the given sub-interval. 13. The method of claim 12 wherein, within each of the n+1 Hamming groups, the binary strings are ordered according to binary value, and further comprising: encoding, by the control circuit, the numbers in the given sub-interval in accordance with the binary values of the binary strings in the Hamming group that corresponds to the given sub-interval. 14. The method of claim 10, further comprising: encoding, by the control circuit, all numbers assigned to a given sub-interval of the 2^n sub-intervals to the same binary string. 15. The method of claim 10, wherein assigning the respective numbers to one of the 2^n non-overlapping sub-intervals comprises: uniformly quantizing, by the control circuit, floating point numbers in the interval into the “2^n” sub-intervals. 16. An apparatus comprising: non-volatile storage;means for accessing digital representations of numbers stored in non-transitory storage, the numbers being in an interval that comprises 2^n non-overlapping sub-intervals that cover the interval, wherein the 2^n sub-intervals are ordered from a first end of the interval to a second end of the interval;means for assigning the respective numbers to one of the 2^n non-overlapping sub-intervals, including means for assigning in accordance with a location of the respective numbers within the interval;means for encoding each of the respective numbers to a selected binary string of 2^n binary strings that are ordered across the interval by Hamming weight; andmeans for storing the selected binary strings in the non-volatile storage. 17. The apparatus of claim 16, wherein the means for assigning the respective numbers to one of the 2^n non-overlapping sub-intervals comprises: means for uniformly quantizing floating point numbers into one of the 2^n sub-intervals that correspond to the 2^n binary strings. 18. The apparatus of claim 17, wherein the 2^n binary strings are clustered across the interval in n+1 Hamming groups, wherein the interval comprises n+1 non-overlapping sub-intervals that correspond to the n+1 Hamming groups, further comprising: means for encoding all numbers in a given sub-interval of the n+1 sub-intervals to the Hamming group that corresponds to the given sub-interval of the n+1 sub-intervals. 19. The apparatus of claim 16, wherein the means for encoding comprises: means for encoding all numbers assigned to a given sub-interval of the 2^n sub-intervals to the same binary string of the 2^n binary strings. 20. The apparatus of claim 16, further comprising: means for decoding the selected binary strings that were stored in the non-volatile storage.