Abstract: A focal plane array (30) for a thermal imaging system (20). The focal plane array (30) may include a number of thermal sensitive elements (42) bounded by a border (41). The thermal sensors (40) may provide a sensor signal output representative of the thermal radiation incident to the focal plane array (30). A multi-layer common electrode (36) may be coupled to the thermal sensitive elements (42) and the border (41). An optical coating (34) sensitive to infrared radiation may be provided in communication with the common electrode (36).

Abstract: A focal plane array (30) for a thermal imaging system (20). The focal plane array (30) may include a number of thermal sensitive elements (42) formed by a first series of slots (78) and a second series of slots (80). The thermal sensors (40) may be bounded by a border (41). The thermal sensors (40) may provide a sensor signal output representative of thermal radiation incident to the focal plane array (30). The first series of slots (78) may include a leading first slot (82) and a trailing first slot (84). Additionally, the first series of slots (78) may include a number of substantially parallel first slots therebetween. The second series of slots (80) may include a leading second slot (86) in a trailing second slot (88). The second series of slots (80) may also include a number of substantially parallel second slots therebetween. One of the first slots may extend beyond the leading second slot (86). Additionally, one of the first slots may extend beyond the trailing second slot (88).

Abstract: A novel multiple level mask (e.g. tri-level mask 36) process for masking achieves a desired thick mask with substantially vertical walls and thus improves the ion milling process of ceramic materials (e.g. BST). An embodiment of the present invention is a microelectronic structure comprising a ceramic substrate, an ion mill mask layer (e.g. photoresist 42) overlaying the substrate, a dry-etch-selective mask layer (e.g. TiW 40) overlaying the ion mill mask layer, the dry-etch-selective mask layer comprising a different material than the ion mill mask layer, a top photosensitive layer (38) overlaying the dry-etch-selective mask layer, the top photosensitive layer comprising a different material than the dry-etch-selective mask layer, and a predetermined pattern formed in the top photosensitive layer, the dry-etch-selective mask layer and the ion mill mask layer. The predetermined pattern has substantially vertical walls in the ion mill mask layer.

Abstract: A hybrid thermal detector (10, 110) includes a focal plane array (20, 120), a thermal isolation structure (40, 140), and an integrated circuit substrate (60, 160). The focal plane array (20, 120) includes thermal sensors (30, 130). The thermal isolation structure (40, 140) includes untrimmed mesa-type formations (44, 146, 148) and mesa strip conductors (42, 142, 144) that provide thermal isolation, signal transport, and structural support of the focal plane array (20, 120) when mounted on the integrated circuit substrate (60, 160). Hybrid thermal detector (10) includes a common electrode (28) which provides a bias voltage to all thermal sensors (30). Hybrid thermal detector (110) has electrically isolated thermal sensors (130), each thermal sensor (130) is supported by mesa strip conductors (142, 144), which provide a bias voltage to and receive a signal voltage from the thermal sensor (130).

Abstract: A hybrid thermal detector (10, 110) includes a focal plane array (20, 120), a thermal isolation structure (40, 140), and an integrated circuit substrate (60, 160). The focal plane array (20, 120) includes thermal sensors (30, 130). The thermal isolation structure (40, 140) includes untrimmed mesa-type formations (44, 146, 148) and mesa strip conductors (42, 142, 144) that provide thermal isolation, signal transport, and structural support of the focal plane array (20, 120) when mounted on the integrated circuit substrate (60, 160). Hybrid thermal detector (10) includes a common electrode (28) which provides a bias voltage to all thermal sensors (30). Hybrid thermal detector (110) has electrically isolated thermal sensors (130), each thermal sensor (130) is supported by mesa strip conductors (142, 144), which provide a bias voltage to and receive a signal voltage from the thermal sensor (130).

Abstract: A hybrid thermal detector (10, 110) includes a focal plane array (20, 120), a thermal isolation structure (40, 140), and an integrated circuit substrate (60, 160). The focal plane array (20, 120) includes thermal sensors (30, 130). The thermal isolation structure (40, 140) includes untrimmed mesa-type formations (44, 146, 148) and mesa strip conductors (42, 142, 144) that provide thermal isolation, signal transport, and structural support of the focal plane array (20, 120) when mounted on the integrated circuit substrate (60, 160). Hybrid thermal detector (10) includes a common electrode (28) which provides a bias voltage to all thermal sensors (30). Hybrid thermal detector (110) has electrically isolated thermal sensors (130), each thermal sensor (130) is supported by mesa strip conductors (142, 144), which provide a bias voltage to and receive a signal voltage from the thermal sensor (130).

Abstract: A thermal detection system (10, 110, 210) includes a focal plane array (20, 120, 220), a thermal isolation structure (40, 140, 240), and an integrated circuit substrate (60, 160, 260). The focal plane array (20, 120, 220) includes a plurality of thermal sensors (30, 130, 230). The thermal isolation structure (40, 140, 240) includes mesa-type formations (44, 146, 148, 244) and bridge structures (42, 142, 144, 242) that provide thermal isolation, signal transport, and structural support of the focal plane array (20, 120, 220) when mounted on the integrated circuit substrate (60, 160, 260). Thermal detection system (10) includes an infrared absorber and common electrode assembly (22) which provides a bias voltage to all thermal sensors (30). Thermal detection system (110) has a plurality of electrically isolated thermal sensors (130), each thermal sensor (130) is supported by bridge structures (142, 144), which provide a bias voltage to and receive a signal voltage from the thermal sensor (130).

Abstract: S-11-hydroxy-10-methylaporphine and its biologically active salt forms are used as 5-HT.sub.1A inhibitors. Since these compounds function as 5-HT.sub.1A they can be used as an antidote for effects of cocaine and as appetite suppressants.

Abstract: Scheduling software provides date and time allocation of resources to a sequence of processes for manufacturing a desired item. Scheduling is performed by a backward-forward method and alternatively by an backward-jump forward method to meet a requested due date. Resources are dynamically allocated to satisfy processes according to pre-established rules for allocation. Also resources are allocated in certain amounts or in a predetermined pattern to minimize waste or left over amounts of the resource. To allocate certain resources, purchase or production of the resource is scheduled first.

Abstract: Certain N,N-dialkyl substituted derivatives of dopamine (DA) increase renal blood flow without affecting cardiac contractility. Particularly effective are N,N-di-n-propyl DA; N-n-propyl-N-n-butyl DA; N-n-propyl-N-n-pentyl DA; N-n-propyl-N-isobutyl DA; and N-n-propyl-N-phenethyl DA. Orally effective versions of these derivatives are obtained by acylating the hydroxyl functions.

Abstract: Smooth muscle tissue relaxation is produced in mammals by internal administration of a compound of the formula: ##STR1## wherein R is alkyl having 1 to 6 carbon atoms, the novel compound 2-N-isopropylamino-1,2,3,4-tetrahydro-5,6,-dihydroxy-naphthalene being preferred. Relief of bronchial asthma and relaxation of the uterine smooth muscle are among the therapeutic effects produced.

Abstract: The compounds represented by the structural formulae: ##STR1## one each used for the treatment of warm blooded mammals with infarcted hearts.The compounds I and II have a totally unpredictable effect on the infarcted heart. An artificial infarct (stoppage of blood vessel) is produced, to mimic the occurrence of a heart attack. Administration of a suitable amount of the compound opens new blood channels in the heart tissue, by-passing the infarcted region, and providing a supply of arterial blood to the area served by the occluded blood vessel. The necrosis which normally occurs in regions of the heart muscle as a result of a stoppage of an artery and resultant oxygen deficiency is largely prevented.