Heating apparatus for a MEMS sensor

What is claimed is: 1. A heating apparatus for a MEMS sensor, comprising: a metallic supply lead element for electric current; a metallic return lead element for electric current; and a defined number of metallic heating elements configured between the supply lead element and the return lead element, a constant electrical current density being configurable in the supply lead element, in the return lead element, and in the heating elements; wherein the heating apparatus is for the MEMS sensor, wherein the supply lead element, on one side of the heating elements, has a definedly decreasing width proceeding in a direction of a current flow over a heating region, and the return lead element, on an opposite side of the heating elements, has a definedly increasing width proceeding in the direction of the current flow over the heating region, and wherein the supply lead element and the return lead element have a reverse symmetry. 2. The heating apparatus as recited in claim 1 , wherein the supply lead element and the return lead element are each, in the heating region, as wide as a total width of the heating elements disposed in the current flow direction. 3. The heating apparatus as recited in claim 1 , wherein profiles of the widths of the supply lead element and of the return lead element are configured linearly, and the heating elements are configured to be of uniform width and to have a spacing from one another which is approximately the same. 4. The heating apparatus as recited in claim 1 , wherein a homogeneous temperature distribution is configurable with the heating elements in the heating region. 5. The heating apparatus as recited in claim 1 , wherein at least one electrically unconnected homogenization element having a definedly higher thermal conductivity than a diaphragm material is configured in the heating region for homogenization of a temperature distribution, the homogenization element being configured between two heating elements. 6. The heating apparatus as recited in claim 5 , wherein the homogenization element is configured in an angular or definedly rounded fashion. 7. The heating apparatus as recited in claim 1 , wherein the heating elements are straight or definedly curved. 8. The heating apparatus as recited in claim 1 , wherein the material of the heating apparatus is at least one of the following: platinum, ruthenium, platinum-ruthenium alloy, titanium, titanium oxide, platinum-titanium alloy, iridium, platinum-titanium-palladium alloy, platinum-zirconium oxide alloy. 9. The heating apparatus as recited in claim 8 , wherein the supply lead element, the return lead element, and the heating elements are configured from the same material. 10. The heating apparatus as recited in claim 8 , wherein the supply lead element, the return lead element, and the heating elements are configured from different materials. 11. The heating apparatus as recited in claim 1 , wherein the heating apparatus is configured in one piece. 12. The heating apparatus as recited in claim 1 , wherein an exact shape as function of a distance is adapted to a geometry of the heating elements so that there is a homogeneous electrical current density distribution. 13. A MEMS sensor, comprising: a heating apparatus disposed on a diaphragm, the heating apparatus including a metallic supply lead element for electric current, a metallic return lead element for electric current, and a defined number of metallic heating elements configured between the supply lead element and the return lead element; wherein an electrical current density, which is approximately constant, is configurable in the supply lead element, in the return lead element, and in the heating elements, and wherein the supply lead element, on one side of the heating elements, has a definedly decreasing width proceeding in a direction of a current flow over a heating region, and the return lead element, on an opposite side of the heating elements, has a definedly increasing width proceeding in the direction of the current flow over the heating region, and wherein the supply lead element and the return lead element have a reverse symmetry. 14. The heating apparatus as recited in claim 13 , wherein a width of the return lead element increases in the current flow direction, wherein a width of the heating elements, and their spacing from one another, are selected so as to produce a maximum region having a homogeneous temperature, and wherein the supply lead element and the return lead element are shaped, and are adapted to the geometry of the heating elements, so that the electrical current density is approximately constant everywhere. 15. A method for manufacturing a heating apparatus for a MEMS sensor, the method comprising: furnishing a metallic supply lead element for electric current; furnishing a metallic return lead element for electric current; and disposing metallic heating elements between the supply lead element and the return lead element, the supply lead element, such that the return lead element, and the heating elements are configured so that an electrical current density, which is approximately constant, is configurable in all the elements; wherein the supply lead element, on one side of the heating elements, has a definedly decreasing width proceeding in a direction of a current flow over a heating region, and the return lead element, on an opposite side of the heating elements, has a definedly increasing width proceeding in the direction of the current flow over the heating region, and wherein the supply lead element and the return lead element have a reverse symmetry. 16. A method of using a heating apparatus, the method comprising: providing a heating apparatus, the heating apparatus including a metallic supply lead element for electric current, a metallic return lead element for electric current, and a defined number of metallic heating elements configured between the supply lead element and the return lead element, a constant electrical current density, which is approximately constant, is configurable in the supply lead element, in the return lead element, and in the heating elements; and using the heating apparatus in a MEMS gas sensor; wherein the supply lead element, on one side of the heating elements, has a definedly decreasing width proceeding in a direction of a current flow over a heating region, and the return lead element, on an opposite side of the heating elements, has a definedly increasing width proceeding in the direction of the current flow over the heating region, and wherein the supply lead element and the return lead element have a reverse symmetry.