Ratio meter of a thermal sensor

What is claimed is: 1. A thermal sensor comprising: a converter circuit configured to convert a temperature-independent signal into a first frequency signal, and to convert a temperature-dependent signal into a second frequency signal; a counting circuit configured to receive at least one of the first frequency signal or the second frequency signal, to count a predetermined number of pulses of the first frequency signal, and to count a number of pulses of the second frequency signal for a time period subsequent and corresponding to the counting of the predetermined number of pulses of the first frequency signal; and a ratio calculator configured to calculate a ratio based on the predetermined number of pulses of the first frequency signal and the counted number of pulses of the second frequency signal. 2. The thermal sensor of claim 1 , further comprising a generator circuit configured to generate the temperature-independent signal and the temperature-dependent signal. 3. The thermal sensor of claim 1 , wherein the converter circuit is a current-to-frequency converter. 4. The thermal sensor of claim 3 , wherein the current-to-frequency converter comprises: a current source comprising a source and a sink; a capacitive device; a first switch device corresponding to the sink of the current source and a second switch device corresponding to the source of the current source, and configured to switch between an open or closed state for charging or discharging the capacitive device; and a comparator circuit configured to receive a voltage signal corresponding to the capacitive device and a reference signal, and to output the first and second frequency signals. 5. The thermal sensor of claim 1 , further comprising a multiplexer configured to select the temperature-independent signal or the temperature-dependent signal to input to the converter circuit. 6. The thermal sensor of claim 1 , wherein the counting circuit comprises: a first counter configured to count the predetermined number of pulses of the first frequency signal, and to output a control signal after counting of the predetermined number of pulses; and a second counter configured to count the number of pulses of the second frequency signal. 7. The thermal sensor of claim 6 , wherein the counting circuit further comprises a switching circuit to selectively couple the converter circuit to the first counter or the second counter. 8. The thermal sensor of claim 7 , wherein the counting circuit further comprises a delay circuit for delaying the control signal for a predetermined time. 9. The thermal sensor of claim 7 , wherein the switching circuit is configured to couple the converter circuit to the first counter or the second counter based on the control signal. 10. The thermal sensor of claim 7 , further comprising a multiplexer configured to select the temperature-independent signal or the temperature-dependent signal to be input to the converter circuit based on the control signal. 11. A method of detecting temperature, the method comprising: converting a temperature-independent signal into a first signal or a temperature-dependent signal received from a thermal sensor into a second signal; counting a predetermined number of pulses of the first signal; counting a number of pulses of the second signal in a time period subsequent and corresponding to the counting of the predetermined number of pulses of the first signal; and calculating a ratio based on the counted number of pulses of the second signal and the predetermined number of pulses of the first signal. 12. The method of claim 11 , further comprising generating the temperature-independent signal and the temperature-dependent signal. 13. The method of claim 12 , wherein the converting of the temperature-independent signal into the first signal comprises: charging a capacitive device to a first predetermined voltage via the temperature-independent signal; and after charging the capacitive device to the first predetermined voltage, discharging the capacitive device to a second predetermined voltage. 14. The method of claim 12 , wherein the converting of the temperature-dependent signal into the second signal comprises: charging a capacitive device to a first predetermined voltage via the temperature-dependent signal; and after charging the capacitive device to the first predetermined voltage, discharging the capacitive device to a second predetermined voltage. 15. The method of claim 11 , wherein the converting of the at least one of the temperature-independent signal into the first signal and the temperature-dependent signal into the second signal comprises selecting to convert the temperature-independent signal or the temperature-dependent signal. 16. The method of claim 11 , further comprising: counting the predetermined number of pulses of the first signal; and in response to the counting of the predetermined number of pulses of the first signal, outputting a control signal. 17. The method of claim 16 , wherein, after outputting of the control signal, counting of the number of pulses of the second signal. 18. The method of claim 16 , further comprising, delaying the control signal for predetermined time. 19. The method of claim 18 , wherein the converting of the at least one of the temperature-independent signal into the first signal and the temperature-dependent signal into the second signal further comprises selecting the temperature-independent signal or the temperature-dependent signal to be converted based on the delayed control signal. 20. A thermal sensor comprising: a converter circuit configured to convert a temperature-independent signal into a first frequency signal, and to convert a temperature-dependent signal into a second frequency signal; a counting circuit configured to receive the first frequency signal or the second frequency signal, to count a predetermined number of pulses of the first frequency signal, and to count a number of pulses of the second frequency signal for a time period corresponding to the counting of the predetermined number of pulses of the first frequency signal; a signal selecting circuit configured to cause the counting circuit to receive the second frequency signal after the counting circuit counts the predetermined number of pulses of the first frequency signal and to cause the counting circuit to receive the first frequency signal after counting the second frequency signal for the time period; and a ratio calculator configured to calculate a ratio based on the predetermined number of pulses of the first frequency signal and the counted number of pulses of the second frequency signal.