For all but the most elementary time-variable linear systems, solutions of the response problem must be particular solutions obtained by machine computation. Thus, the insight into system response characteristics, which is gained from analytic procedures, is lost. This paper proposes an approximate representation of the time-variable weighting function

(system response at time

to a unit impulse at time

) which permits a straightforward analytic evaluation of response for both deterministic and stochastic inputs. Although the evaluation of the approximate representation may require machine computation, once the approximate representation is obtained, no further machine calculations are necessary. The approximation has the form

where the

are arbitrary approximating functions. Methods are given for evaluating the

. Several families of orthonormal approximating functions are discussed which simplify both the evaluation and utilization of the approximation. For example, when the

have rational Laplace transforms, the

are computed directly from the solutions of certain time-variable linear differential equations. For stationary stochastic inputs, simple series expressions for the output correlation function are derived, and it is shown that propitious choice of the

greatly reduces the number of integrations which must be made in evaluating the series. Two example problems illustrate the feasibility of the proposed procedures.