Method of measuring internal resistance of battery cell and device therefor

What is claimed is: 1 . A battery management device comprising: one or more passive balancing circuits ( 100 ) provided for each of one or more battery cells (Cell- 1 , . . . , Cell-N), wherein each passive balancing circuit ( 100 ) includes a balancing resistor (BR- 1 , . . . , BR-N) and a switching element (SW- 1 , . . . , SW-N) for selectively discharging each battery cell (Cell- 1 , . . . , Cell-N) through the balancing resistor (BR- 1 , . . . , BR-N); and a control unit ( 120 ) configured to: determine an alternating current internal resistance of a target battery cell that is subject to cell balancing based on a voltage of the target battery cell before and after a target switching element that is the switching element corresponding to the target battery cell is turned on, and determine a direct current internal resistance of the target battery cell based on an amount of change in the voltage of the target battery cell during a time period after a predetermined time elapses from a time point when the target switching element is turned on, wherein the control unit ( 120 ) controls a plurality of target switching elements corresponding to a plurality of target battery cells which are selected from among the battery cells (Cell- 1 , . . . , Cell-N) included in a battery stack ( 14 ) together so that cell balancing for the plurality of target battery cells is performed simultaneously and determines internal resistances of the plurality of target battery cells based on simultaneously measured voltages for the plurality of target battery cells. 2 . The battery management device of claim 1 , wherein the control unit ( 120 ) measures the voltage of the target battery cell for each cycle with a preset period, and determines the alternating current internal resistance using a difference between the voltage of the target battery cell measured in a first cycle immediately before the target switching element is turned on and the voltage of the target battery cell measured in a second cycle immediately after the target switching element is turned on. 3 . The battery management device of claim 1 , wherein the control unit ( 120 ) determines the alternating current internal resistance based on a ratio in which the voltage of the target battery cell is divided into an equivalent series resistor (R 1 ) of the target battery cell and a target balancing resistor connected to the target switching element when the target switching element is turned on. 4 . The battery management device of claim 1 , wherein the control unit ( 120 ) is further configured to: open a relay connecting the battery stack ( 140 ) in parallel with another battery stack prior to measuring the alternating current internal resistance; select, from among an odd-numbered group including odd-numbered battery cells in the battery stack ( 140 ) and an even-numbered group including even-numbered battery cells in the battery stack ( 140 ), a group including a highest voltage battery cell that is a battery cell having a highest voltage among the one or more battery cells (Cell- 1 , . . . , Cell-N) as a first group, and select another group as a second group; turn on first switching elements corresponding to first battery cells in the first group, determine the alternating current internal resistance of the first battery cells; turn off the first switching elements; turn on second switching elements corresponding to second battery cells in the second group; and determine the alternating current internal resistance of the second battery cells. 5 . A method for measuring an internal resistance of a battery, the method comprising: measuring a voltage of a target battery cell that is subject to cell balancing (S 400 ); turning on a switching element of a passive balancing circuit ( 100 ) corresponding to the target battery cell (S 420 ); measuring a voltage of the target battery cell after the target switching element is turned on (S 440 ); determining an alternating current internal resistance of the target battery cell based on the measured voltages (S 460 ); and determining a direct current internal resistance of the target battery cell based on an amount in change of the voltage of the target battery cell during a time period after a predetermined time elapses from a time when the switching element is turned on (S 480 ), wherein in the turning on of the target switching element, a plurality of switching elements corresponding to a plurality of target battery cells, which are selected from among a plurality of battery cells (SW- 1 , . . . , SW-N) constituting a battery stack ( 14 ), are controlled together so that cell balancing for the plurality of target battery cells is performed at the same time, and wherein in the determining of the alternating current internal resistance, the internal resistances of the plurality of target battery cells are determined based on simultaneously measured voltages.