Apparatus and method for estimating degree of aging of secondary battery

What is claimed is: 1. An apparatus of estimating a degree of aging of a secondary battery, the apparatus comprising: a current measuring unit configured to measure a current of the secondary battery and output a current measurement; a temperature measuring unit configured to measure a temperature of the secondary battery and output a temperature measurement; and a control unit operatively coupled to the current measuring unit and the temperature measuring unit, wherein the control unit is configured to: determine the current and the temperature of the secondary battery by receiving a current measurement signal and a temperature measurement signal respectively from the current measuring unit and the temperature measuring unit; determine a state of charge of the secondary battery from the current of the secondary battery; determine an operation state of the secondary battery as one of a calendar state and a cycle state by using the current of the secondary battery; determine a degree of calendar aging in the calendar state by applying a cumulative degree-of-aging model to a predefined degree-of-calendar-aging profile corresponding to the determined state of charge and the determined temperature while the secondary battery is in the calendar state; determine a degree of cycle aging in a cycle state by applying the cumulative degree-of-aging model to a predefined degree-of-cycle-aging profile corresponding to the state of charge, the temperature, and the current of the secondary battery while the secondary battery is in the cycle state; and determine, as the degree of aging of the secondary battery, a weighted average value that is calculated for the determined degree of calendar aging and the determined degree of cycle aging on the basis of calendar time for which the calendar state is maintained and cycle time for which the cycle state is maintained, and wherein, whenever a predetermined reference time elapses while the secondary battery is in the cycle state, the control unit is configured to perform: (i) determining the predefined degree-of-cycle profile used to calculate a change in the degree of cycle aging for the reference time by using the state of charge, the temperature, and the current of the secondary battery; (ii) determining a reference equivalent time on the determined degree-of-cycle-aging profile; (iii) determining the change in the degree of cycle aging for the reference time from the reference equivalent time by using the degree-of-cycle-aging profile; and (iv) determining the degree of cycle aging of the secondary battery by integrating the determined change in the degree of cycle aging with a previously determined degree of cycle aging. 2. The apparatus according to claim 1 , wherein, whenever a predetermined reference time elapses while the secondary battery is in the calendar state, the control unit is configured to cyclically perform: (i) determining the predefined degree-of-calendar-aging profile used to calculate a change in the degree of calendar aging for the reference time by using the state of charge and the temperature of the secondary battery; (ii) determining a reference equivalent time on the determined degree-of-calendar-aging profile; (iii) determining the change in the degree of calendar aging for the reference time from the reference equivalent time by using the degree-of-calendar-aging profile; and (iv) determining the degree of calendar aging of the secondary battery by integrating the determined change in the degree of calendar aging with a previously determined degree of calendar aging. 3. The apparatus according to claim 2 , wherein the control unit is configured to determine, as the reference equivalent time, time corresponding to the previously determined degree of calendar aging on the determined degree-of-calendar-aging profile. 4. The apparatus according to claim 1 , wherein the control unit is configured to determine, as the reference equivalent time, time corresponding to the previously determined degree of cycle aging on the determined degree-of-cycle-aging profile. 5. The apparatus according to claim 1 , wherein the control unit is configured to: calculate the weighted average value by respectively weighting the degree of calendar aging and the degree of cycle aging with the calendar time and the cycle time; or calculate the weighted average value by respectively weighting the degree of calendar aging and the degree of cycle aging with a log-scaled calendar time and a log-scaled cycle time. 6. The apparatus according to claim 1 , further comprising a memory unit operatively coupled to the control unit, wherein the control unit is configured to store the determined degree of aging of the secondary battery in the memory unit. 7. The apparatus according to claim 1 , further comprising a communication unit operatively coupled to the control unit, wherein the control unit is configured to output the determined degree of aging of the secondary battery to an outside of the apparatus via the communication unit. 8. A method of estimating a degree of aging of a secondary battery, the method comprising: (a) determining a current and a temperature of the secondary battery by using a current measuring unit and a temperature measuring unit; (b) determining a state of charge of the secondary battery from the current of the secondary battery; (c) determining an operation state of the secondary battery as one of a calendar state and a cycle state by using the current of the secondary battery; (d) determining a predefined degree-of-calendar-aging profile corresponding to the determined state of charge and the determined temperature while the secondary battery is in the calendar state, and determining a degree of calendar aging in the calendar state by applying a cumulative degree-of-aging model to the determined degree-of-calendar-aging profile; (e) determining a predefined degree-of-cycle-aging profile corresponding to the determined state of charge, the determined temperature, and the determined current of the secondary battery while the secondary battery is in the cycle state, and determining a degree of cycle aging in the cycle state by applying the cumulative degree-of-aging model to the determined degree-of-cycle-aging profile; and (f) determining, as the degree of aging of the secondary battery, a weighted average value that is calculated for the determined degree of calendar aging and the determined degree of cycle aging on the basis of calendar time for which the calendar state is maintained and cycle time for which the cycle state is maintained, wherein the operation step (e) comprises cyclically updating the degree of cycle aging by repeatedly performing operation steps (e1) to (e4) of: (e1) determining the predefined degree-of-cycle-aging profile used to calculate a change in the degree of cycle aging for reference time by using the state of charge, the temperature, and the current of the secondary battery; (e2) determining reference equivalent time on the determined degree-of-cycle-aging profile; (e3) determining the change in the degree of cycle aging for the reference time from the reference equivalent time by using the degree-of-cycle-aging profile; and (e4) determining the degree of cycle aging of the secondary battery by integrating the determined change in the degree of cycle aging. 9. The method according to claim 8 , wherein the operation step (d) comprises cyclically updating the degree of calendar aging by repeatedly performing operation steps (d1) to (d4) of: (d1) determining the predefined degree-of-calendar-aging profile used to calculate a change in the degree of calendar aging for reference time by using the state of charge and the temperature of the s