초록 ▼

A distribution cabinet (1) for accommodating weak-current distribution installations, in particular for arranging outdoors, having a base box (2), an outer cabinet body (3) with at least one door (4), a cabinet cover (5), and an inner installation frame (6), the installation frame (6) being

A distribution cabinet (1) for accommodating weak-current distribution installations, in particular for arranging outdoors, having a base box (2), an outer cabinet body (3) with at least one door (4), a cabinet cover (5), and an inner installation frame (6), the installation frame (6) being made up of profile sections (50), of which the cross-sectional shapes has two insertion pockets (51a,b), of which the insertion directions (52a,b) run at right angles to one another.

대표청구항 ▼

A distribution cabinet (1) for accommodating weak-current distribution installations, in particular for arranging outdoors, having a base box (2), an outer cabinet body (3) with at least one door (4), a cabinet cover (5), and an inner installation frame (6), the installation frame (6) being

A distribution cabinet (1) for accommodating weak-current distribution installations, in particular for arranging outdoors, having a base box (2), an outer cabinet body (3) with at least one door (4), a cabinet cover (5), and an inner installation frame (6), the installation frame (6) being made up of profile sections (50), of which the cross-sectional shapes has two insertion pockets (51a,b), of which the insertion directions (52a,b) run at right angles to one another. ignment area; (b) performing a high-energy/high-dose implant through the at least one opening and the material stack so as to form at least one deep subcollector region in the semiconductor substrate; (c) lithographically forming a second patterned layer (photoresist or dielectric) predominately outside the first patterned layer in the alignment area; and (d) etching through the material stack to form alignment marks in the underlying semiconductor substrate using the first patterned layer as an alignment mark mask. 162-164. Blumenthal, D.J. et al.; "WDM Optical IP Tag Switching with Packet-Rate Wavelength Conversion and Subcarrier Multiplexed Addressing," OFC 1999, Conference Digest, pp. 162-164, 1999. Lee, J. et al.; "Secure Communication Using Chaos," Globecom 1995, pp. 1183-1187, Singapore, Nov. 14-16, 1995. Bennett, Charles H., "Experimental Quantum Cryptography," Journal of Cryptology, vol. 5, pp. 3 thru 28, (1992). Faist, J. et al.; "High-Power Continuous-Wave Quantum Cascade Lasers," IEEE Journal of Quantim Electronics, vol. 34, No. 2, pp. 336-343, Feb., 1998. Guillemot, Christian; "Optical Packet Switching for SDM High Speed Backbones," Power Point Presentation at 24th European Conference on OPtical Communication, Madrid, Spain, pp. 1-43, Sep. 20-24, 1998. Gambini, Piero et al.; "Transparent Optical Packet Switching: Network Architecture and Demonstrators in the Keops Project," IEEE Journal on Selected Areas in Communications, vol. 16, No. 7, pp. 1245-1259, Sep., 1998. Hunter, David K.; "Waspnet: A Wavelength Switched Packet Network," IEEE Communications Magazine,pp. 120-129, Mar., 1999. Kato, K. et al.;"32×32 Full-Mesh (1024 Path) Wavelength-Routing WDM Network Based On Uniform Loss Cyclic Frequency Arrayed-Waveguide Grating," Electronics Letters, vol. 36, No. 15, pp. 1294-1296, Jul. 20, 2000. Takada, K. et al.; "480 Channel 10 GHz Spaced Multi/Demultiplexer," Electronics Letters, vol. 35, No. 22, pp. 1964-1966, Oct. 28, 1999. Neber, S. et al.; "Tunable Laser Diodes With Type II Superlattice in the Tuning Region," Semiconductor Science Technology, vol. 13, pp. 801-805, 1998. Chan, M. et al.; "The Effect of Carrier-Induced Change on the Optical Properties of AlGaAs-GaAs Intermixed Quantum Wells," IEEE Journal on Selected Topics in Quantum Electronics, vol. 4, No. 4, pp. 685-694, Jul./Aug., 1998. Shim, J. et al.; "Refractive Index and Loss Changes Produced by Current Injection in InGaAs(P)InGaAsP Multiple Quantum-Well (MQW) Waveguides," IEEE Journal on Selected Topics in Quantum Electronics, vol. 1, No. 2, pp. 408-415, Jun., 1995. Mason, B. et al.; "Widely Tunable Sampled Grating DBR Laser With Integrated Electroabsorption Modulator," IEEE Photonics Technology Letters, vol. 11, No. 6, pp. 638-640, Jun., 1999. Kaminow, I.P. et al.; "A Wideband All-Optical WDM Network," IEEE Journal on Selected Areas of Communications, vol. 14, No. 5, pp. 780-799, Jun., 1996. Maxemchuk, N.F.; "The Manhattan Street Network," Proceedings on IEEE Globecom '85, pp. 255-261, Dec., 1985. Budiman, A. et al.; "Multigigabit Optical Packet Switch for Self-Routing Networks with Subcarrier Addressing," Technical Digest, Paper TuO4, pp. 90-91, OFC, 1992. Way, W.I, et al.; "Self-Routing WDM High-Capacity Sonet Ring Network," Technical Digest, Paper TuO2, pp. 86-87, OFC, 1992. Hofmeister, R.T. et al.; "Cord: Optical Packet-Switched Network Testbed," Fiber and Integrated Optics, vol. 16, pp. 199-219, 1997. Park, E. et al.; "Self-Routing of Wavelength Packets Using an All Optical Wavelength Shifter and QPSK Subcarrier Routing Control," IEEE Photonics Technology Letters, vol. 8, pp. 936-940, Jul., 1996. Shell, M. et al.; "Experimental Demonstration of an All-Optical Routing Node For Multihop Wavelength Routed Networks," IEEE Photonics Technology Letters, vol. 8, pp. 1391-1393, 1996. Wang, B.H. et al.; "Demonstration of Gigabit WDMA Networks Using Parallel-Processed Sub-Carrier Hopping Pilot-Tone (P3) Signaling Technique," IEEE Photonics Technology Letters, vol. 8, pp. 933-934, Jul., 1996. Shieh, W. et al.; "A Wavelength-Routing Node Using Multifunctional Semiconductor Optical Amplifiers and Multiple-Pilot-Tone-Coded Subcarrer Control Headers," IEEE Photonics Technology Letters, vol. 9, pp. 1268-1270, Sep., 1997. Jiang, X. et al.; "All Optical Wavelength Independent Packet Header Replacement Using a Long CW Region Generated Directly from the Packet Flag," IEEE Photonics Technology Letters, vol. 9, pp. 1638-1640, Nov., 1998. Blumenthal, D.J. e