Saw filter with a large bandwidth

What is claimed is: 1. A filter arrangement, comprising: a first double mode surface acoustic wave (DMS) filter; and a second DMS filter, wherein: the first DMS filter and the second DMS filter are connected to each other in parallel between a first node and a second node of the filter arrangement; each of the first DMS filter and the second DMS filter comprises two DMS tracks, connected in series; a center frequency of the first DMS filter is larger than a center frequency of the second DMS filter; a first DMS track of the two DMS tracks of the first DMS filter and a second DMS track of the two DMS tracks of the first DMS filter each comprises an input or output converter and at least a first coupling converter and a second coupling converter; the input or output converter of the first DMS track is coupled with the first coupling converter of the first DMS track via a first capacitive element and with the second coupling converter of the first DMS track via a second capacitive element; and the input or output converter of the second DMS track is coupled with the first coupling converter of the second DMS track via a third capacitive element and with the second coupling converter of the second DMS track via a fourth capacitive element. 2. The filter arrangement according to claim 1 , further comprising a serial resonator connected in series to the first DMS filter and the second DMS filter. 3. The filter arrangement according to any of the preceding claims, wherein: the two DMS tracks of the first DMS filter are connected to each other via the first and second coupling converters; the two DMS tracks of the second DMS filter are connected to each other via two or more coupling converters; and for each DMS track of the first DMS filter and the second DMS filter, the coupling converters are arranged in phase opposition, and earth connections of the coupling converters are connected to each other but not to an external potential. 4. The filter arrangement according to claim 1 , wherein each DMS track of the first DMS filter and the second DMS filter is structured as a metallization on at least one lithium niobate substrate and coated with a dielectric covering layer, which is positioned directly on top of the metallization. 5. The filter arrangement according to claim 4 , wherein the dielectric covering layer has a temperature coefficient TCF that is lower than that of the substrate or is opposed to that of the substrate. 6. The filter arrangement according to claim 1 , wherein, parallel to each of the first node and the second node of the filter arrangement, a coil is respectively connected to ground. 7. The filter arrangement according to claim 1 , wherein a finger connection sequence in the two DMS tracks of the first DMS filter is selected such that, at least in one instance, two adjacent terminal converter fingers of different coupling converters are potential-carrying converter fingers. 8. The filter arrangement according to claim 1 , further comprising: a balanced port, wherein each of the first DMS filter and the second DMS filter at the balanced port has two anti-phase output converters or one V-split converter, which comprises two partial converters that are arranged side by side in longitudinal direction and that are electrically connected to each other in parallel. 9. A method, comprising: using a filter arrangement as a receive filter, the filter arrangement comprising: a first double mode surface acoustic wave (DMS) filter; and a second DMS filter, wherein: the first DMS filter and the second DMS filter are connected to each other in parallel between a first node and a second node of the filter arrangement; each of the first DMS filter and the second DMS filter comprises two DMS tracks connected in series; a center frequency of the first DMS filter is larger than a center frequency of the second DMS filter; a first DMS track of the two DMS tracks of the first DMS filter and a second DMS track of the two DMS tracks of the first DMS filter each comprises an input or output converter and at least a first coupling converter and a second coupling converter; the input or output converter of the first DMS track is coupled with the first coupling converter of the first DMS track via a first capacitive element and with the second coupling converter of the first DMS track via a second capacitive element; and the input or output converter of the second DMS track is coupled with the first coupling converter of the second DMS track via a third capacitive element and with the second coupling converter of the second DMS track via a fourth capacitive element operating the receive filter for two adjacent bands; and performing, via the receive filter, simultaneous reception in the two bands within a Carrier Aggregation mode.