The Starfleet Survival Guideby David Mack, Timothy M. Earls, Timothy M.M. Earls
As the brave men and women of Starfleet carry out their duties mapping countless solar systems, greeting new species and establishing ties with civilizations large and small they live, work, and face the possibility that they could die in space. How do Starfleet's finest survive the countless dangers to be discovered as they boldly go where no one has
As the brave men and women of Starfleet carry out their duties mapping countless solar systems, greeting new species and establishing ties with civilizations large and small they live, work, and face the possibility that they could die in space. How do Starfleet's finest survive the countless dangers to be discovered as they boldly go where no one has gone before? Find out with this special edition of The Starfleet Survival Guide!
Contains up tp date, declassified information on
STANDARD EQUIPMENT NONSTANDARD USES
For further reference, or if you are considering and exciting and fulfilling career in the diplomatic and scientific fleet of the United Federation of Planets, please contact your local Starfleet representative.
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1.01 Causing Localized Seismic Disruptions with Tricorder and/or Combadge Signals
Although creating controlled seismic events is extremely dangerous, they can be an effective deterrent if executed properly blocking the path of a pursuer or group of pursuers in a wilderness setting by causing the collapse of a large volume of earth, rock, snow, or other material.
This effect is sometimes easy to create with well-placed phaser blasts, but if phasers are not available or have malfunctioned, a variety of terrains might prove susceptible to disruption through the use of ultrasonic and hypersonic signals from a combadge or tricorder. Regions with great quantities of loose rock, muddy earth, or heavy accumulations of snow or similar frozen precipitation can be induced to collapse by using focused sonic waves to reduce their overall strength and cohesion.
For maximum effect, such controlled events should be directed into gullies, narrow canyon passages, or other close areas, providing the greatest degree of obstruction to a pursuer. However, great care should be taken not to execute such a tactic too close to any settled area, or in a location where there is an unacceptably high risk of the controlled event triggering subsequent, uncontrolled events that might lead to unwanted collateral damage.
If the disruption is to be effected using a tricorder:
Scan the target area for its overall mass and molecular cohesion.
Press the GEO-1 switch on the tricorder to initialize geological scan protocols.
Select sense option I for internal sensors, followed by command protocol Alpha to set the scan type to the geological mechanics subroutine.
Run the "GEO Mechanics" subroutine to pinpoint weak areas and zones of maximum stress.
Select the GEO-2 control to calculate the necessary frequency and amplitude of signal to induce a seismic disruption.
Small volumes of low mass are relatively easy to disrupt with a tricorder; disruptions of greater than 10 metric tons or of highly cohesive material require more power and will necessitate the creation of a collimated signal from the tricorder and any other signal sources immediately available, such as other tricorders and combadges.
If the disruption is to be effected using a combadge:
Using a combadge, the process of locating vulnerable areas and selecting appropriate disruption frequencies becomes one of trial and error, with manual adjustments being made through the ultrasonic and hypersonic frequencies until the trigger frequency is found. Caution should be exercised to ensure that while searching for the correct frequency to disrupt the target area, other zones of instability particularly if they are underfoot or overhead are not disrupted during the process.
Open the back access panel and use a fine-grade, nonconductive tool to adjust the RF transceiver the triangular circuit assembly located below the lower right-hand corner of the subspace transceiver assembly through its preset frequency and amplitude test series.
Narrow the transmission bandwidth by adjusting the aperture control, a circular element located at the topmost area of the combadge's internal assembly, to direct the beam.
Set the signal aperture to a field-of-view (FoV) of approximately .25 to .35 degrees of arc.
Target the top point of the combadge at the target area.
Cycle the RF test settings through the ultrasonic and hypersonic frequency ranges until the target area begins to show signs of disruption.
As soon as disruption effects become visible, leave the RF settings in place and increase the gain to the RF circuit from the combadge's sarium krellide power cell until the desired level of collapse has occurred.
Copyright © 2002 by Paramount Pictures. All Rights Reserved.
Meet the Author
David Mack is the New York Times bestselling author of more than twenty-five novels, including the Star Trek Destiny and Cold Equations trilogies. He co-developed the acclaimed Star Trek Vanguard series and its sequel, Star Trek: Seekers. His writing credits span several media, including television (for episodes of Star Trek: Deep Space Nine), film, short fiction, magazines, comic books, computer games, and live theater. He currently resides in New York City.
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Very interesting if you are into the stae trek fiction universe.
Its just how-tos on fictional equipment