Remote temperature sensing

1 . A method comprising: determining, based on a first local V BE value and a local ΔV BE value that represents a difference between a pair of local voltage values, a first value that corresponds to a temperature of a local sensor core, wherein a first local voltage value of the pair of local voltage values corresponds to a first voltage drop across a local p-n junction of the local sensor core, and wherein the first local V BE value corresponds to a second voltage drop across the local p-n junction of the local sensor core; determining, based on a second local V BE value and a remote ΔV BE value that represents a difference between a pair of remote voltage values, a second value that corresponds to a temperature of a remote sensor core, wherein the second local V BE value corresponds to a third voltage drop across the local p-n junction, and wherein the pair of remote voltage values each correspond to respective voltage drops across a remote p-n junction of the remote sensor core while the remote p-n junction is biased at different respective current levels; and determining the temperature of the remote sensor core based at least on the first value and the second value. 2 . The method of claim 1 , wherein the first value is a first duty cycle of a charge sharing sigma-delta analog-to-digital converter (ADC) configured to generate a bitstream, and wherein the second value is a second duty cycle of the ADC. 3 . The method of claim 2 , wherein the determining the second value comprises: integrating, by the ADC and during a mixed sensing operation, the remote ΔV BE value to determine a next bit of the bitstream in response to determining that a current bit of the bitstream is a first logical value; integrating, by the ADC and during the mixed sensing operation, the second local V BE value to determine the next bit of the bitstream in response to determining that the current bit of the bitstream is a second logical value; and determining the second duty cycle of the ADC based on the bitstream determined by the ADC during the mixed sensing operation. 4 . The method of claim 3 , wherein determining the first value comprises: integrating, by the ADC and during a local sensing operation, the local ΔV BE value to determine the next bit of the bitstream in response to determining that the current bit of the bitstream is the first logical value; integrating, by the ADC and during the local sensing operation, the first local V BE value to determine the next bit of the bitstream in response to determining that the current bit of the bitstream is the second logical value; and determining the first duty cycle of the ADC based on the bitstream determined by the ADC during the local sensing operation. 5 . The method of claim 4 , wherein the bitstream determined by the ADC during the local sensing operation includes a same quantity of logical values as the bitstream determined by the ADC during the mixed sensing operation. 6 . The method of claim 4 , wherein the temperature of the remote p-n junction is determined approximately according to the following equation: T R = ln  ( N L ) ln  ( N R ) · 1 - μ L 1 - μ R · μ R μ L · T L wherein T R is the temperature of the remote p-n junction, T L is the temperature of the local sensor core, μ L is the first duty cycle of the ADC, μ R is the second duty cycle of the ADC, N L is a ratio of current levels at which the local sensor core is biased during the local sensing operation, and N R is a ratio of current levels at which the remote sensor core is biased during the mixed sensing operation. 7 . The method of claim 1 , further comprising determining the pair of remote voltage values represented by the remote ΔV BE value by at least: determining, at a first time, a first remote voltage value of the pair of remote voltage values as a voltage drop across the remote p-n junction while the remote p-n junction is biased with a first current; and determining, at a second time, a second remote voltage value of the pair of remote voltage values as a voltage drop across the remote p-n junction while the remote p-n junction is biased with a second current. 8 . The method of claim 1 , further comprising determining the pair of local voltage values represented by the local ΔV BE value by at least: determining, at a first time, the first local voltage value of the pair of local voltage values as a voltage drop across the local p-n junction while the local p-n junction is biased with a first current; and determining, at a second time, a second local voltage value of the pair of local voltage values as a voltage drop across the local p-n junction while the local p-n junction is biased with a second current. 9 . The method of claim 1 , wherein the local p-n junction is a first local p-n junction, the method further comprising determining the pair of local voltage values represented by the local ΔV BE value by at least: determining the first local voltage value of the pair of local voltage values as a voltage drop across the first local p-n junction while the first local p-n junction is biased with a first current; and determining a second local voltage value of the pair of local voltage values as a voltage drop across a second local p-n junction of the local sensor core while the second local p-n junction is biased with a second current. 10 . The method of claim 1 , wherein the temperature of the remote sensor core is different than the temperature of the local sensor core. 11 . A device comprising: an analog-to-digital converter (ADC) configured to determine, based on a first local V BE value and a local ΔV BE value that represents a difference between a pair of local voltage values, a first value that corresponds to a temperature of a local sensor core, wherein a first voltage value of the pair of local voltage values corresponds to a first voltage drop across a local p-n junction of the local sensor core, and wherein the first local V BE value corresponds to a second voltage drop across the local p-n junction of the local sensor core, wherein the ADC is further configured to determine, based on a second local V BE value and a remote ΔV BE value that rep