Abstract: Disclosed are methods for making microwave circuits using thickfilm components. In an embodiment, the method includes depositing a dielectric over a ground plane, and then forming a conductor on the dielectric. The conductor is formed by depositing a conductive thickfilm on the dielectric and then “subsintering” the conductive thickfilm. In one embodiment, before the subsintering, the conductive thickfilm is patterned to define at least one conductor. In another embodiment, after the subsintering, the conductive thickfilm is patterned to define at least one conductor. After subsintering, the conductive thickfilm is etched to expose the conductor(s), and the conductor(s) are then fired at a full sintering temperature.

Abstract: In a method for making a microwave circuit, a first dielectric is deposited over a ground plane, and then a conductor is formed on the first dielectric. A second dielectric is then deposited over the conductor and first dielectric, thereby encapsulating the conductor between the first and second dielectrics. In one embodiment, a ground shield layer is formed over the first and second dielectrics by 1) precoating the first and second dielectrics with a metallo-organic layer, and then 2) depositing a thickfilm ground shield layer over the precoat layer. Alternately, a ground shield layer is formed over the first and second dielectrics by 1) placing a polymer screen over the first and second dielectrics, and applying pressure to the polymer screen until it at least partially conforms to a contour of the dielectrics, and then 2) printing a thickfilm ground shield layer through the polymer screen.

Abstract: Disclosed is a method for forming a conductor on a dielectric. The method commences with the deposition of a conductive thickfilm on the dielectric, followed by a “subsintering” of the conductive thickfilm. Either before or after the subsintering, the conductive thickfilm is patterned to define at least one conductor. After subsintering, the conductive thickfilm is etched to expose the conductor(s), and the conductor(s) are then fired. A brief chemical etch may be used after the final firing step if improved wire-bondability is required.

Abstract: Disclosed are methods for making microwave circuits using thickfilm components, the thickfilm components including: a first, multi-layer thickfilm dielectric deposited on a ground plane; a thickfilm conductor deposited on the first thickfilm dielectric; a second, multi-layer thickfilm dielectric deposited on the first dielectric and conductor to encapsulate the conductor; a thickfilm ground shield layer deposited over the first and second dielectrics; and thickfilm resistors deposited in close proximity to the first and second dielectrics.

Abstract: Disclosed is a method for depositing a thickfilm dielectric on a substrate. The method commences with the deposition of a first layer of thickfilm dielectric on the substrate, followed by an air drying of the first layer to allow solvents to escape, thereby increasing the porosity of the first layer. The first layer is then oven dried. Thereafter, additional layers of thickfilm dielectric are deposited on top of the first layer, with each layer being oven dried after it is deposited. The deposited layers are then fired.

Abstract: Disclosed are methods for making microwave circuits using thickfilm components, the thickfilm components including: a first, multi-layer thickfilm dielectric deposited on a ground plane; a thickfilm conductor deposited on the first thickfilm dielectric; a second, multi-layer thickfilm dielectric deposited on the first dielectric and conductor to encapsulate the conductor; a thickfilm ground shield layer deposited over the first and second dielectrics; and thickfilm resistors deposited in close proximity to the first and second dielectrics.

Abstract: Disclosed is a method for forming a conductor on a dielectric. The method commences with the deposition of a conductive thickfilm on the dielectric, followed by a “subsintering” of the conductive thickfilm. Either before or after the subsintering, the conductive thickfilm is patterned to define at least one conductor. After subsintering, the conductive thickfilm is etched to expose the conductor(s), and the conductor(s) are then fired. A brief chemical etch may be used after the final firing step if improved wire-bondability is required.

Abstract: A glass material is deposited upon a ceramic substrate and then fired at an elevated temperature in air. Screen printed resistor elements formed on the glass material are fired, lapped, and annealed.