Exhibits 1 - 4

3960-EX-PL-1993 Text Documents

SOUTHWEST RESEARCH INSTITUTE

2003-01-13ELS_59734

Exhibit No. 01 Modulating Necessary Frequency Power Emission Signal Bandwidth (A) (B) (C) (D) (E) (F) (G) 80 kHz 2 KW Z2kW MEAN AO N/A N/A 111 kHz 2 kW 2kW MEAN AOo N/A N/A 130 kHz 2kW 2kW MEAN Ao N/A N/A 160 kHz 2 kW 2 kW MEAN AO N/A N/A {—200 kHz 2kW 2 kW MEAN AO N/A N/A |~250 kHz 2kW 2kW MEAN Ao N/A N/A 326 kHz 2kW 2kW MEAN Ao N/A N/A *@00 kHzZ 2kKW 2kW MEAN AO N/A N/A 520 kHz 2kW 2kW MEAN Ao N/A N/A 640 kHz 2kW 2kW MEAN A0 N/A N/A 810 kHz 2kW 2kW MEAN AO N/A N/A 1.0 MHz 2kW 2kW MEAN AO N/A N/A 1.3 MHzZ 2kW 2kW MEAN AO N/A N/A 1.995 MHz 2kW 2kW MEAN A0 N/A N/A 2.6 MHz 2kW ZkW MEAN AOo N/A N/A 3.2 MHzZ 2kW 2kW MEAN AOo N/A N/A

Exhibit No. 01 (continued) Modulating Necessary Frequency Power Emission Signal Bandwidth (A) (B) (C) (D) (E) (F) (G) 4.06 MHz 2kW 2kW MEAN Ao N/A N/A 5.1 MHzZ 2kW 2kW MEAN Ao N/A N/A —*6.525 MHzZ 2kW 2kW MEAN Ao N/A N/A 8.1 MHz 2kW 2kW MEAN A0 N/A N/A 10.1 MHz 2kW 2 kW MEAN AO N/A N/A 13.560 MHz 2kW 2 kW MEAN AO N/A N/A 16.000 MHz 2kW 2kW MEAN AO0 N/A N/A 20.02 MHz 2kW 2kW MEAN AO N/A N/A 27.120 MHzZ 2kW 2 kW MEAN AOo N/A N/A 33.3 MHz 2kW 2kW MEAN Ao N/A N/A 40.680 MHz 2kW 2kW MEAN AOo N/A N/A 52 MHz 2kW 2kW MEAN AO N/A N/A 65 MHz 2kW 2kW MEAN AO N/A N/A 81 MHz 2kW 2kW MEAN Ao N/A N/A *"108 MHz 2kW 2kW MEAN Ao N/A N/A

Exhibit No. 01 (continued) Modulating Necessary Frequency Power Enmission Signal Bandwidth (A) (B) (C) (D) (E) (F) (G) +130 mHz 2kW 2kW MEAN a0 N/A N/A 160 MHz 2kW 2kW MEAN AOo N/A N/A 209 MHz 0. SkW 15. SkW MEAN Ao N/A N/A p 260 MHz 0 . 5kW 15. 8kW MEAN A0 N/A N/A y 327 MHz 0. 5kW 15. 8SkW MEAN AOo N/A N/A 415 MHz 0. 5kW 15. 8kW MEAN AO N/A N/A 523 MHz 0. 5kW 15. 8kW MEAN Ao N/A N/A 661 MHz 0 . SkW 15. 8kW MEAN Ao N/A N/A 830 MHz 0 . 5kW 15. 8kW MEAN AOo N/A N/A 915 MHz 0 . 5kW 15. 8kW MEAN A0 N/A N/A 1.29 GHzZ . 2kW 6. 32kW MEAN A0 N/A N/A 1.86 GHz — 2KW 6. 32kW MEAN AO N/A N/A 2.1 GHz » 2kKkW 6. 32kW MEAN A0o N/A N/A 2 .45 GHz & 2KW 6. 32kW MEAN AO N/A N/A 3.29 GHz . 2kW 6. 32kW MEAN Ao N/A N/A 7'\4.30 CHz . 2KW 6.32kW MEAN A0 N/A N/A ( (.

Exhibit No. 01 (continued) Modulating Necessary Frequency Power Emission Signal Bandwidath (A) (B) (C) (D) (E) (F) (G) 5.800 GHz . 2kW 6. 32kW MEAN AOo N/A N/A 6.6 GHz & 2kKW 6 . 32kW MEAN Ao N/A N/A 8 .5 GHz — 2kW 6. 32kW MEAN AO N/A N/A 10.495 GHz — 2kW 6. 3 2kW MEAN AO N/A N/A 13.22 GHZz . 2kW 6. 32kW MEAN A0o N/A N/A 18 GHz & 2KkW 6. 32kW MEAN A0 N/A N/A C C

Exhibit 02 Antenna Type: Modified Beverage Antenna Frequency Range: 10 kHz — 1.6 MHz Width of Beanm in Degrees at the Half—Power Point: 187.1 Orientation: Horizontally Polarized Power Gain: 1 Antenna Type: 3 Meter Whip (Transformer coupled) Frequency Range: 1.6 — 10 MHz Width of Beam in Degrees at the Half—Power Point: 187.1 Orientation: Vertically Polarized Power Gain: 1 Antenna Type: 2 Meter Whip (Transformer coupled or Base loaded) Frequency Range: 10 —25 MHz wWidth of Beanmn in Degrees at the Half—Power Point: 187.1 Orientation: Vertically Polarized Power Gain: 1 Antenna Type: High Power Biconical Dipole Frequency Range: 25 —200 MHz Width of Beam in Degrees at the Half—Power Point: 187.1 Orientation: Used both Vertically and Horizontally Polarized Power Gain: 1 Antenna Type: Ridged Waveguide Horn or Log Periodic Array Frequency Range: 200 MHz — 1 GHz Width of Bean in Degrees at the Half—Power Point: 40.77 Orientation: Used both Vertically and Horizontally Polarized Power Gain: 31.6 Antenna Type: Ridged Waveguide Horn Frequency Range: 1 CGHz — 8 GHz Width of Beanm in Degrees at the Half—Power Point: 40.77 Orientation: Used both Vertically and Horizontally Polarized Power Gain: 31.6 Antenna Type: Rectangular Wavegqguide Horn Frequency Range: 8 GHz — 18 GHz Width of Bearmr in Degrees at the Half—Power Point: 40.77 Orientation: Used both Vertically and Horizontally Polarized Power Gain: 31.6 NOTE: The higher frequency antenna (200 MHz.and above) which tend to have narrower beams of radiation may need to be mounted at elevations and angles that will maximize their radiation through windows or other openings. This may be needed for adequate tests of cluster or dash—mounted electronics.

Exhibit 03 The proposed program of experimentation is designed to ensure electromagnetic compatibility (EMC) in electronic control systems ugsed for automotive applications. Testing techniques will be conducted on complete systems (whole—vehicles) since components systenmns, which may not be susceptible to electromagnetic interference (EMI) when tested by themselves, may be susceptible when installed as part of a larger or whole—vehicle system. Open— field testing will provide both a reference and perturbation—free environment in which actual operating conditions of the eqiupment under test (EUT) can be simulated. The method of testing will consist of irradiating the EUT at a selected frequency and monitoring the system for susceptibility. The time of irradiation will be linmitd to several minutes in duration, but of sufficient time to insure the credibility of the testing. The test site will consist of the existing open area test site located at Southwest Research Insitute (SwRI). A description of this site is on file with the FCC under the September 1982 report "Description of Measurement Facility" prepared for the FCC Laboratory Division, P.O. Box 40 Laurel, Maryland 20810. A copy of this report is included.

Exhibit 04 Experimentation is done on a contractual basis and is subject to the needs and fluctuation of the EMI/EMC testing market. The experimental license is needed on a continuing basis to be able to respond in a timely fashion to project requirements. The length of the proposed EMI/EMC testing will be greater than two years.


Document Created: 2003-01-13 08:14:13
Document Modified: 2003-01-13 08:14:13
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