Battery impedance spectra measurement

What is claimed is: 1. An apparatus comprising: a voltage measurement circuit having first measurement inputs and a first measurement output, the first measurement inputs adapted to be coupled across a battery cell; a current measurement circuit having second measurement inputs and a second measurement output, the second measurement inputs adapted to be coupled to the battery cell; and a controller circuit having control inputs and control outputs, the control inputs coupled to the first measurement output and the second measurement output, and the controller circuit configured to: receive, via the control inputs, digital samples of a current signal that flows through the battery cell within a measurement period; receive, via the control inputs, digital samples of a voltage signal across the battery cell within the measurement period; generate first voltage spectral components based on performing a first transform operation on the digital samples of the voltage signal; generate a current spectrum based on performing a second transform operation on the digital samples of the current signal; generate second voltage spectral components based on a first condition of the battery cell before the measurement period and a second condition of the battery cell after the measurement period; generate a voltage spectrum including the first voltage spectral components and the second voltage spectral components; and provide, via the control outputs, an impedance spectrum of the battery cell based on the voltage spectrum and the current spectrum. 2. The apparatus of claim 1 , wherein at least one of the first transform operation or the second transform operation is based on a Laplace transform operation. 3. The apparatus of claim 2 , wherein the controller circuit is configured to: receive first parameters of a first analytical Laplace transform expression of a first function that approximates variations of the voltage signal within the measurement period; receive second parameters of a second analytical Laplace transform expression of a second function that approximates variations of the current signal within the measurement period; generate the first voltage spectral components based on the digital samples of the voltage signal and the first parameters; and generate the current spectrum based on the digital samples of the current signal and the second parameters. 4. The apparatus of claim 3 , wherein each of the first function and the second function comprises at least one of: a piecewise linear interpolation function, a step function, or a pulse function. 5. The apparatus of claim 4 , wherein the controller circuit is configured to select the first function and the second function from a set of candidate functions based on at least one of: characteristics of the voltage signal and the current signal, or a sampling rate of the voltage signal and the current signal. 6. The apparatus of claim 2 , wherein the controller circuit is configured to: determine whether the battery cell operates in an operation condition in which the first condition matches the second condition; and responsive to determining that the battery cell operates in the operation condition in which the first condition matches the second condition: receive, via the control inputs, a first digital sample of a first voltage before the measurement period; receive, via the control inputs, a second digital sample of a second voltage after the measurement period; determine a voltage difference between the first voltage and the second voltage based on the first digital sample and the second digital sample; and generate the second voltage spectral components based on computing a Laplace transform of the voltage difference. 7. The apparatus of claim 6 , wherein each of the first voltage and the second voltage include an open circuit voltage (OCV) of the battery cell. 8. The apparatus of claim 6 , wherein: the operation condition includes a first operation condition or a second operation condition; the current signal is sinusoidal; the first operation condition includes multiple cycles of the sinusoidal current signal flowing through the battery cell, and the measurement period spans a last cycle of the multiple cycles; and the second operation condition includes the current signal flowing through the battery cell when the battery cell is in a well-rested condition, and the current signal stops flowing through the battery cell within a relaxation period prior to an end of the measurement period. 9. The apparatus of claim 2 , wherein the controller circuit is configured to: determine whether the battery cell operates in an operation condition in which the first condition does not match the second condition; and responsive to determining that the battery cell operates in the operation condition in which the first condition does not match the second condition: determine a first Laplace transform based on the first condition; determine a second Laplace transform based on the second condition; and generate the second voltage spectral components based on the first Laplace transform and the second Laplace transform. 10. The apparatus of claim 9 , wherein: the controller circuit is configured to determine the first and second Laplace transforms based on an electrical model of the battery cell, the electrical model including a series resistor, a series capacitor, and one or more parallel resistor-capacitor networks coupled across a positive terminal and a negative terminal of the battery cell; the first condition includes first internal voltages of the electrical model before the measurement period; and the second condition includes second internal voltages of the electrical model after the measurement period. 11. The apparatus of claim 10 , wherein the controller circuit is configured to: generate third voltage spectral components based on: (a) estimates of resistances and capacitances of the respective resistors and capacitors of the electrical model; (b) estimates of internal voltages of the electrical model; and (c) the current spectrum; determining differences between the first voltage spectral components and the third voltage spectral components; update the estimates of the resistance, the capacitances, and the internal voltages based on performing an iterative optimization operation to reduce the differences; and generate the second voltage spectral components based on the updated estimates of the resistance, the capacitances, and the internal voltages. 12. The apparatus of claim 11 , further comprising a memory; wherein the controller circuit is configured to: store, in the memory, a table of the estimates of the resistances, the capacitances, and the internal voltages of the electrical model of the battery cell across different temperatures and different depths of discharge (DODs); receive the estimates from the table based on a temperature and a DOD of the battery cell; and start the optimization operation using the estimates from the table. 13. The apparatus of claim 12 , wherein the controller circuit is configured to determine the DOD based on a relationship between DODs and OCVs of the battery cell, the relationship being determined based on a discharge/relaxation test in which the battery cell is repeatedly discharged with a sequence of discharge current pulses, and in which the OCV of the battery cell is measured between two discharge current pulses. 14. The apparatus of claim 12 , wherein the controller circuit is configured to update the table in the memory based on the updated estimates of the resistances, the capacitances, a