• A Single-Transistor, L-Band Telemetering Transmitter

      D'Elio, C.; Poole, J.; RCA Electronic Components and Devices (International Foundation for Telemetering, 1965-05)
    • A Six-Channel Physiological Telemetering System

      Robrock, R. B., II; Ko, W. H.; Case Institute of Technology (International Foundation for Telemetering, 1965-05)
      A six channel FM/FM physiological telemetering system was designed to measure two surface temperatures, an internal temperature, the respiration rate, and position and muscle spasm of a paralyzed patient. Tunnel diode subcarrier oscillators operating from a constant-current source provided excellent temperature and long term stability while permitting a complete transmission package with size 0.6" x 2.5" x 2.5" and weight 15 gm. A compatible transistorized receiving system was also constructed.
    • A Solid-State Microwave Relay System

      Beanland, Charles J.; Microwave Associates, Inc. (International Foundation for Telemetering, 1965-05)
      The paper outlines the design parameters and system performance of a solid-state microwave relay equipment. The design is suitable for the transmission of television signals, multichannel telephony and wideband data information. Circuit techniques are described and illustrative numbers quoted for an equipment operating in the 2 KMc/s microwave relay band.
    • Standards Re-evaluation for Wideband Magnetic Tape Recording

      Ratner, Vic A.; Defense Electronics, Inc. (International Foundation for Telemetering, 1965-05)
    • Subminiature Inductive Transducers used with High Carrier Frequencies

      Straugh, H.; Associated Engineering, Ltd. (International Foundation for Telemetering, 1965-05)
      This paper describes the development and construction of subminiature inductive transducers which can be operated with carrier frequencies up to 400 Kcs. Two types have been developed for operation at 150°C which are able to withstand an acceleration of 2000g, and a high-temperature (600°C) transducer is now in the final stage of development. The body of the low-temperature transducer is made of high-temperature epoxy resin, and that of the high-temperature transducer of ceramic material. Iron wire is used as core material to reduce eddy current losses. The dimensions of the transducers are 0.25 inch diameter and 0.5 inch long, and 0.125 inch diameter and 0.25 inch long, including terminations. A linear displacement of the armature material can be measured at distances up to 0.01 inch, and because of the high carrier frequency, the vibration of this armature can be up to 30 Kcs. Both ferrous and non-ferrous armature material can be used for displacement measurement. The inductive transducers have been used to measure piston movement at right angles to the cylinder axis in an internal combustion engine, in conjunction with a lead-out system. Tests using a telemetry system (radio link) are now being carried out. Details of the construction and performance are described and future development discussed. The use of the inductive transducer as a pressure transducer is also mentioned.
    • Telemetering Physiologic Data from Athletes

      Rose, Kenneth D.; University of Nebraska (International Foundation for Telemetering, 1965-05)
      Employing a team composed of physicians, electrical engineers, and specialists in physical education, significant dynamic physiological data has been gathered by means of radiotelemetry from athletes undergoing strenuous effort, participating in team sports, and from spectators viewing football games. Using a transistorized A.M.-F.M. transmitter carried in a padded compartment strapped comfortably onto the low back and weighing 30 oz. complete, ECG, pulse, temperature and respiration signals have been transmitted for distances up to 500 yards. The multiple technical problems surrounding distance telemetering of physiological information during active and vigorous muscular effort are discussed. Somatic muscle interference, the most troublesome artefact in dynamic electrocardiography, has been successfully circumvented by instantaneous recording of data from the momentarily inactive subject. Application of computer techniques to the analysis of exercise electrocardiograms must await procedural improvement and standardization and collection of adequate data on which to base valid programming.
    • Telemetry for 250,000-G Gun Environment

      Finger, Daniel W.; Harry Diamond Laboratories (International Foundation for Telemetering, 1965-05)
      Techniques for packaging telemetry components and systems to withstand gun launch accelerations up to 250,000-g are discussed, and the necessary and sufficient conditions for survival are established. The principal requirements are that all voids be eliminated from the package and that encapsulating resins be adequately contained. The ultra-high-g projectiles used in hypervelocity research for which these telemeters were designed are briefly described. In addition, a brief description is given of high-g telemetry systems used in the gun-fired rockets and projectiles of project HARP.
    • Telemetry from Meteorological Satellites

      Stampfl, R. A.; A & M Division, Goddard Space Flight Center (International Foundation for Telemetering, 1965-05)
    • TELTRAC, A Telemetry Tracking Acquisition Aid System

      Knowlton, Orin H., Jr.; Canoga Electronics Corporation (International Foundation for Telemetering, 1965-05)
      TELTRAC, A Telemetry Tracking Acquisition Aid System, was manufactured by Canoga Electronics Corporation for the National Aeronautics and Space Administration to augment and update the Project Mercury systems for Project Gemini. In addition, many of the components of the TELTRAC System have been supplied to retrofit and upgrade the original Project Mercury systems. The features of the TELTRAC System that are new in comparison to previously existing Telemetry Trackers are the TELAR II Antenna and the Model 3403 Receiver, which employs both cross-correlation and phase-lock techniques. The TELTRAC System design criteria and a system error analysis, with particular emphasis on multipath errors, are discussed in this article. The detailed design of the TELTRAC System, as well as its subsystems, is also presented.
    • Two-Way Telemetry for Hospital Use

      Johnston, E. B.; I.T.T. Federal Labs (International Foundation for Telemetering, 1965-05)
      A radio telemetry system for transmitting physiological data from a patient is used in a receiver complex to locate the patient. Methods of stimulating the patient for research or remedial control are discussed.
    • The Use of Binary Cyclic Codes in the Generation of Two Other Classes of High Security Codes

      Brothman, A.; Horowitz, L. M.; Halpern, S. J.; Brothman, E. H.; Reiser, R. D.; Transitel International Corporation (International Foundation for Telemetering, 1965-05)
    • A Wideband UHF Transmitter for Space Applications

      Digiovanni, J. J.; Murphy, R. T.; Lockheed Missiles and Space Division (International Foundation for Telemetering, 1965-05)
      This paper describes the design and performance of a frequency-modulated 10watt S-band transmitter. Analogue frequency response is in excess of 7 Mc and digital signals at rates up to 10 megabits per second are transmitted satisfactorily. This extra wideband transmitter, ruggedized for space applications, utilizes a solid state exciter for signal generation, a traveling wave tube amplifier for power amplification, and a solid state traveling wave tube power supply that will withstand critical atmospheric pressures. A detailed analysis of rf bandwidth requirements and the state of the semiconductor art at the time of transmitter design resulted in the exciter taking the form of a 70 Mc voltage controlled oscillator whose output is amplified and converted to the S-band output frequency by means of broadband varactor harmonic generators. Production versions of this transmitter have consistently demonstrated satisfactory orbital operation. Laboratory data has indicated a minimum rf power output of 10 watts at base-plate temperatures ranging from -35° to +75° Centigrade. Baseband response is from 10 cycles to more than 7 Mc at ±6 Mc frequency deviation.