Tesla statistics mark I: Difference between revisions
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Updated 341022 (David S. de Lis) | Updated 341022 (David S. de Lis) | ||
Small Corrections 350505 (David S. de Lis) | Small Corrections 350505 (David S. de Lis) | ||
More corrections 351012 (David S. de Lis) | More corrections 351012-351013 (David S. de Lis) | ||
Corrected crew numbers according to automation (360601) (David S. de Lis) | |||
BASIC STATISTICS | BASIC STATISTICS | ||
| Line 14: | Line 15: | ||
PHYSICAL SPECIFICATIONS | PHYSICAL SPECIFICATIONS | ||
Length : 386 m | Length : 386 m | ||
Beam : 138 m | Beam : 138 m | ||
Draft : 65 m | Draft : 65 m | ||
Displacement : 834,418 mt | Displacement : 834,418 mt | ||
COMPLEMENT | COMPLEMENT | ||
Total : | Total : 158 | ||
Officers : | Officers : 10 | ||
Crew : | Crew : 93 | ||
Passengers : 20 (standard) | Passengers : 20 (standard) | ||
Marines : 35 | Marines : 35 | ||
| Line 27: | Line 28: | ||
PROPULSION SYSTEMS | PROPULSION SYSTEMS | ||
Warp Propulsion System | Warp Propulsion System | ||
Drive Type : ILN- | Drive Type : ILN-610d Mk I | ||
Number : 2 (variable) | Number : 2 (variable) | ||
Main Reactor : FRAM-933 | Main Reactor : FRAM-933 | ||
| Line 46: | Line 47: | ||
Maximum Cruise Speed : 9.0 | Maximum Cruise Speed : 9.0 | ||
Sustainable for 12 hours: 9.6 | Sustainable for 12 hours: 9.6 | ||
(Flight Mode) | (Flight Mode) | ||
Standard Cruise Speed : 8.0 | Standard Cruise Speed : 8.0 | ||
Maximum Cruise Speed : 9. | Maximum Cruise Speed : 9.6 | ||
Sustainable for 12 hours: 9.85 | Sustainable for 12 hours: 9.85 | ||
Maximum Emergency Speed : 9.95 | Maximum Emergency Speed : 9.95 | ||
Core Failure | Core Failure Immenent : 9.97 | ||
ARMAMENT | ARMAMENT | ||
Phaser, Type XI | Phaser, Type XI | ||
Number : | Number : 6 banks | ||
Range : 345,000 km | Range : 345,000 km | ||
Arcs : Saucer module dorsal array ( | Arcs : Saucer module dorsal array (p/s) | ||
Saucer module ventral array ( | Saucer module ventral array (p/s) | ||
Secondary hull aft array | Secondary hull aft array | ||
Secondary hull ventral array | Secondary hull ventral array | ||
| Line 95: | Line 95: | ||
The TESLA class destroyer is the direct successor of the venerable | The TESLA class destroyer is the direct successor of the venerable | ||
FEYNMAN, based on the | FEYNMAN, based on the succesful modifications to the USS TESLA II, | ||
from where it inherits the name. | from where it inherits the name. | ||
As the TESLA II, the TESLA-class ships are white and have a very | |||
As the TESLA II, the TESLA-class ships are | |||
streamlined hull, with variable geometry Warp nacelles. It has been | streamlined hull, with variable geometry Warp nacelles. It has been | ||
upgraded to the newest gravitic plane propulsion systems, which allow | upgraded to the newest gravitic plane propulsion systems, which allow | ||
for much improved speeds and maneuverability at sublight speeds. | for much improved speeds and maneuverability at sublight speeds. | ||
The sensors on the TESLA class are improved versions of the old | The sensors on the TESLA class are improved versions of the old | ||
| Line 118: | Line 107: | ||
computer core has been installed to improve sensors synchronization | computer core has been installed to improve sensors synchronization | ||
speeds, systems automation and redundancy, and augmented resolution. | speeds, systems automation and redundancy, and augmented resolution. | ||
The increased size and displacement are justified by the better | |||
The increased displacement | sublight speeds and sensor power. | ||
and sensor power | |||
Due to the improved automations, the crew has been reduced accordingly. | Due to the improved automations, the crew has been reduced accordingly. | ||
Feynman-class original description follows. | |||
After successfully testing and improving the DELPHI array deep space | |||
After successfully testing and improving the DELPHI array deep space | sensor system on the USS FENRIS, it was decided to implement it in a | ||
sensor system on the USS FENRIS, it was decided to implement it in a | smaller class of vessel with a strong emphasis on scientific use. It | ||
smaller class of vessel with a strong emphasis on scientific use. It | quickly became evident that a medium-sized ship of 300 to 450 crew | ||
quickly became evident that a medium-sized ship of 300 to 450 crew | |||
would be the platform suited best, filling the gap between the WOLFE- | would be the platform suited best, filling the gap between the WOLFE- | ||
class frigates and the DIOGENES-class cruisers both in size and crew. | class frigates and the DIOGENES-class cruisers both in size and crew. | ||
To avoid the mass and energy consumption that comes along with a third | To avoid the mass and energy consumption that comes along with a third | ||
nacelle to shape the subspace field for scanning purposes, the FEYNMAN | nacelle to shape the subspace field for scanning purposes, the FEYNMAN | ||
class uses a variable warp nacelle geometry, based on a two nacelle | class uses a variable warp nacelle geometry, based on a two nacelle | ||
design. It also uses the minimum reflectance surface for minimal | design. It also uses the minimum reflectance surface for minimal | ||
background noise, making the ship appear black from most view angles, | background noise, making the ship appear black from most view angles, | ||
as well as the thruster control system used on it's bigger cousin. | as well as the thruster control system used on it's bigger cousin. | ||
The ship's saucer section is somewhat elongated with a more streamlined | The ship's saucer section is somewhat elongated with a more streamlined | ||
arrowhead appearance to facilitate a more efficient warp bubble at | arrowhead appearance to facilitate a more efficient warp bubble at | ||
higher warp speeds, while the engineering section is resembling the | higher warp speeds, while the engineering section is resembling the | ||
shape of an elongated AMBASSADOR-class design with variable position | shape of an elongated AMBASSADOR-class design with variable position | ||
warp nacelles. The hull allows an emergency separation but cannot | warp nacelles. The hull allows an emergency separation but cannot | ||
reassemble in space. There is no Captain's yacht to allow the bottom | reassemble in space. There is no Captain's yacht to allow the bottom | ||
of the saucer section to be shaped for optimum deflector use. The | of the saucer section to be shaped for optimum deflector use. The | ||
auxiliary shuttlebay doors open forward. | auxiliary shuttlebay doors open forward. | ||
| Line 160: | Line 140: | ||
Details on the modification: | Details on the modification: | ||
The variable nacelle geometry is not explicitly required for warp drive, | The variable nacelle geometry is not explicitly required for warp drive, | ||
but serves the purpose of stabilizing and refining the warp field for | but serves the purpose of stabilizing and refining the warp field for | ||
the main delphi array which is operating on subspace frequencies during | the main delphi array which is operating on subspace frequencies during | ||
warp. When operating in a different configuration it can serve to | warp. When operating in a different configuration it can serve to | ||
increase warp field efficiency (greatly reducing the sensor efficiency) | increase warp field efficiency (greatly reducing the sensor efficiency) | ||
at high speed to optimze energy consumption and effectively increasing | at high speed to optimze energy consumption and effectively increasing | ||
speed. | speed. | ||
The low reflectance surface is reducing sensor ghosts of all kinds, | The low reflectance surface is reducing sensor ghosts of all kinds, | ||
making scans more accurate and providing additional passive protection | making scans more accurate and providing additional passive protection | ||
against being scanned. To compensate for this in non-hostile encounters, | against being scanned. To compensate for this in non-hostile encounters, | ||
the protocols have been modified to allow to provide beacons for own and | the protocols have been modified to allow to provide beacons for own and | ||
friendly vessels. | friendly vessels. | ||
| Line 177: | Line 157: | ||
Adittional modifications: | Adittional modifications: | ||
The USS TESLA II has been retrofited an ORACLE-IIr sensor suite from the | The USS TESLA II has been retrofited an ORACLE-IIr sensor suite from the | ||
CHARON-class FF. This has called for modifications on the main and lateral | CHARON-class FF. This has called for modifications on the main and lateral | ||
arrays, and the addition of an extra computer core, to deal with the extra | arrays, and the addition of an extra computer core, to deal with the extra | ||
computating power needed. The existing, experimental SESR (System of | computating power needed. The existing, experimental SESR (System of | ||
Enhanced Sensors Resolution) type II installed before the upgrade has been | Enhanced Sensors Resolution) type II installed before the upgrade has been | ||
changed by a modified Type IIId module, designed on purpose to operate with | changed by a modified Type IIId module, designed on purpose to operate with | ||
the ORACLE-IId. The SESR has been attached to the new computer core to | the ORACLE-IId. The SESR has been attached to the new computer core to | ||
provide faster operations. All these modifications on the sensors have made | provide faster operations. All these modifications on the sensors have made | ||
unnecessary the black coating, high reflective surface of the Feynman-class | unnecessary the black coating, high reflective surface of the Feynman-class | ||
DDs, thus the TESLA has a white hull like any other Fleet vessel. | DDs, thus the TESLA has a white hull like any other Fleet vessel. | ||
Additionally, the USS TESLA II has been retrofitted a Gen. IV D-Warp drive | Additionally, the USS TESLA II has been retrofitted a Gen. IV D-Warp drive | ||
system, a modification of that on the MONTU-class CL, with aid of the | system, a modification of that on the MONTU-class CL, with aid of the | ||
TSYKLON-class DD systems. Warp core has been replaced by a new FRAM-930 | TSYKLON-class DD systems. Warp core has been replaced by a new FRAM-930 | ||
unit, to allow for the extra energy consumption, allowing her to easily | unit, to allow for the extra energy consumption, allowing her to easily | ||
reach the Kappa band for sustained periods of time with less stress to the | reach the Kappa band for sustained periods of time with less stress to the | ||
systems. The nacelles have been upgraded to the ILN-500 series, which allows | systems. The nacelles have been upgraded to the ILN-500 series, which allows | ||
the ship smoother Warp drive response, specially considering the dynamic | the ship smoother Warp drive response, specially considering the dynamic | ||
nature of the Warp field geometry on FEYNMANs, without sacrificing top speeds. | nature of the Warp field geometry on FEYNMANs, without sacrificing top speeds. | ||
All these modifications have increased the ship displacement by 70,000 mt, | All these modifications have increased the ship displacement by 70,000 mt, | ||
which has reduced somewhat the maneuverability of the ship at impulse speeds, | which has reduced somewhat the maneuverability of the ship at impulse speeds, | ||
although the Warp speeds are maintaned and even enhanced. | although the Warp speeds are maintaned and even enhanced. | ||
| Line 203: | Line 183: | ||
History: | History: | ||
The Feynman class is named in honor of the twentieth century Nobel prize | The Feynman class is named in honor of the twentieth century Nobel prize | ||
winning physicist/philosopher/teacher, Richard P. Feynman, whose simple | winning physicist/philosopher/teacher, Richard P. Feynman, whose simple | ||
but elegant demonstration of O Ring failure during the Challenger hearings | but elegant demonstration of O Ring failure during the Challenger hearings | ||
lead to improved standards of safety for early earth spacecraft. He is | lead to improved standards of safety for early earth spacecraft. He is | ||
also considered one of the fathers of Nanotechnology; an award named is | also considered one of the fathers of Nanotechnology; an award named is | ||
his honor has been given since the late twentieth century. | his honor has been given since the late twentieth century. | ||
In October 2405 the project approval was received. A rescaled version | In October 2405 the project approval was received. A rescaled version | ||
of the DELPHI Array began construction. In May 2406 the keel was laid, | of the DELPHI Array began construction. In May 2406 the keel was laid, | ||
and the actual construction on the primary hull began. In June 2406 the | and the actual construction on the primary hull began. In June 2406 the | ||
nacelle construction began. August 2406 saw the joinging of primary and | nacelle construction began. August 2406 saw the joinging of primary and | ||
secondary hulls and the installation of the DELPHI array began. In | secondary hulls and the installation of the DELPHI array began. In | ||
September 2406 the installation of the remaining communication, navigation | September 2406 the installation of the remaining communication, navigation | ||
systems and computer core followed. | systems and computer core followed. | ||
October 2406 the Warp Drive was tested, followed by finishing the | October 2406 the Warp Drive was tested, followed by finishing the | ||
installation of the rescaled DELPHI array in November, and its calibration | installation of the rescaled DELPHI array in November, and its calibration | ||
and test in December 2406. In January 2407 the construction was completed | and test in December 2406. In January 2407 the construction was completed | ||
and the ship commissioned for system evaluation as NX-66000 USS Feynman. | and the ship commissioned for system evaluation as NX-66000 USS Feynman. | ||
The USS TESLA, NCC-66001 was commissioned in July 2407 and lost in August | The USS TESLA, NCC-66001 was commissioned in July 2407 and lost in August | ||
2408 to warp soliton waves while trying to save a planet. In recognition, | 2408 to warp soliton waves while trying to save a planet. In recognition, | ||
Starfleet ordered the commission of the USS TESLA II, NCC-66101 in September | Starfleet ordered the commission of the USS TESLA II, NCC-66101 in September | ||
2412, the ship was commissioned and attached as escort and extension ship to | 2412, the ship was commissioned and attached as escort and extension ship to | ||
DS13, in GOLD Fleet, in April 2413. | DS13, in GOLD Fleet, in April 2413. | ||
| Line 240: | Line 220: | ||
Ship Design by Armin Lenz and Kelli Belden | Ship Design by Armin Lenz and Kelli Belden | ||
Starfleet Engineering Revision by Armin Lenz, Kelli Belden, | Starfleet Engineering Revision by Armin Lenz, Kelli Belden, | ||
Jeffrey Jenkins, Jeffrey Finocchiaro, Kristopher Kolman | Jeffrey Jenkins, Jeffrey Finocchiaro, Kristopher Kolman | ||
Revised by David S | Revised by David S de Lis | ||
[Note: Names of the ships should follow names of Famous Scientists as shown | [Note: Names of the ships should follow names of Famous Scientists as shown | ||
by the above examples.] | by the above examples.] | ||
</pre> | </pre> | ||
Latest revision as of 08:09, 2 June 2024
321019
Updated 341022 (David S. de Lis)
Small Corrections 350505 (David S. de Lis)
More corrections 351012-351013 (David S. de Lis)
Corrected crew numbers according to automation (360601) (David S. de Lis)
BASIC STATISTICS
Class Name : TESLA
Classification : Surveyor
Type : DD (Destroyer)
Model Number : I (USS MAXWELL, NCC-66201)
PHYSICAL SPECIFICATIONS
Length : 386 m
Beam : 138 m
Draft : 65 m
Displacement : 834,418 mt
COMPLEMENT
Total : 158
Officers : 10
Crew : 93
Passengers : 20 (standard)
Marines : 35
PROPULSION SYSTEMS
Warp Propulsion System
Drive Type : ILN-610d Mk I
Number : 2 (variable)
Main Reactor : FRAM-933
Impulse System
Drive Type : GDP-1 (Gravitic Dynamic Planing Drive, Model 1)
Number : 2
Secondary Reactor: FRIF-465 Network
Thruster Control : Quickstep
D-Warp Drive : Dim-IV-F2ai
VELOCITY
(Sensor Mode)
Standard Cruise Speed : 6.0
Maximum Cruise Speed : 9.0
Sustainable for 12 hours: 9.6
(Flight Mode)
Standard Cruise Speed : 8.0
Maximum Cruise Speed : 9.6
Sustainable for 12 hours: 9.85
Maximum Emergency Speed : 9.95
Core Failure Immenent : 9.97
ARMAMENT
Phaser, Type XI
Number : 6 banks
Range : 345,000 km
Arcs : Saucer module dorsal array (p/s)
Saucer module ventral array (p/s)
Secondary hull aft array
Secondary hull ventral array
Photon Torpedo, MkXXIII Seeking/Direct
Number : 2 tubes
Range : 3,000,000 km
Arcs : 1 forward, 1 aft
Deflector System : FD-7c Cocoon multiphasic deflector system
OTHER SYSTEMS
Transporters
Standard, 6-person : 4
Emergency, 22-person: 2
Cargo : 3
Shuttle Bays : 2 (1 main, 1 auxilliary)
Embarked Craft
Shuttlepod : 4
Personnel Shuttle, Small: 4
D-Warp Shuttle : 4
Cargo Shuttle : 1
Runabout : 0
Enhancements:
ORACLE-IId.3 : 1
SESR Module (type IIId) : 2
Computers : 2 additional cores
Gen. IV D-Warp : 2 nodes + necessary equipment
Notes:
The TESLA class destroyer is the direct successor of the venerable
FEYNMAN, based on the succesful modifications to the USS TESLA II,
from where it inherits the name.
As the TESLA II, the TESLA-class ships are white and have a very
streamlined hull, with variable geometry Warp nacelles. It has been
upgraded to the newest gravitic plane propulsion systems, which allow
for much improved speeds and maneuverability at sublight speeds.
The sensors on the TESLA class are improved versions of the old
ORACLE-IId systems, with the adapted SESR IIId systems. An additional
computer core has been installed to improve sensors synchronization
speeds, systems automation and redundancy, and augmented resolution.
The increased size and displacement are justified by the better
sublight speeds and sensor power.
Due to the improved automations, the crew has been reduced accordingly.
Feynman-class original description follows.
After successfully testing and improving the DELPHI array deep space
sensor system on the USS FENRIS, it was decided to implement it in a
smaller class of vessel with a strong emphasis on scientific use. It
quickly became evident that a medium-sized ship of 300 to 450 crew
would be the platform suited best, filling the gap between the WOLFE-
class frigates and the DIOGENES-class cruisers both in size and crew.
To avoid the mass and energy consumption that comes along with a third
nacelle to shape the subspace field for scanning purposes, the FEYNMAN
class uses a variable warp nacelle geometry, based on a two nacelle
design. It also uses the minimum reflectance surface for minimal
background noise, making the ship appear black from most view angles,
as well as the thruster control system used on it's bigger cousin.
The ship's saucer section is somewhat elongated with a more streamlined
arrowhead appearance to facilitate a more efficient warp bubble at
higher warp speeds, while the engineering section is resembling the
shape of an elongated AMBASSADOR-class design with variable position
warp nacelles. The hull allows an emergency separation but cannot
reassemble in space. There is no Captain's yacht to allow the bottom
of the saucer section to be shaped for optimum deflector use. The
auxiliary shuttlebay doors open forward.
Details on the modification:
The variable nacelle geometry is not explicitly required for warp drive,
but serves the purpose of stabilizing and refining the warp field for
the main delphi array which is operating on subspace frequencies during
warp. When operating in a different configuration it can serve to
increase warp field efficiency (greatly reducing the sensor efficiency)
at high speed to optimze energy consumption and effectively increasing
speed.
The low reflectance surface is reducing sensor ghosts of all kinds,
making scans more accurate and providing additional passive protection
against being scanned. To compensate for this in non-hostile encounters,
the protocols have been modified to allow to provide beacons for own and
friendly vessels.
Adittional modifications:
The USS TESLA II has been retrofited an ORACLE-IIr sensor suite from the
CHARON-class FF. This has called for modifications on the main and lateral
arrays, and the addition of an extra computer core, to deal with the extra
computating power needed. The existing, experimental SESR (System of
Enhanced Sensors Resolution) type II installed before the upgrade has been
changed by a modified Type IIId module, designed on purpose to operate with
the ORACLE-IId. The SESR has been attached to the new computer core to
provide faster operations. All these modifications on the sensors have made
unnecessary the black coating, high reflective surface of the Feynman-class
DDs, thus the TESLA has a white hull like any other Fleet vessel.
Additionally, the USS TESLA II has been retrofitted a Gen. IV D-Warp drive
system, a modification of that on the MONTU-class CL, with aid of the
TSYKLON-class DD systems. Warp core has been replaced by a new FRAM-930
unit, to allow for the extra energy consumption, allowing her to easily
reach the Kappa band for sustained periods of time with less stress to the
systems. The nacelles have been upgraded to the ILN-500 series, which allows
the ship smoother Warp drive response, specially considering the dynamic
nature of the Warp field geometry on FEYNMANs, without sacrificing top speeds.
All these modifications have increased the ship displacement by 70,000 mt,
which has reduced somewhat the maneuverability of the ship at impulse speeds,
although the Warp speeds are maintaned and even enhanced.
History:
The Feynman class is named in honor of the twentieth century Nobel prize
winning physicist/philosopher/teacher, Richard P. Feynman, whose simple
but elegant demonstration of O Ring failure during the Challenger hearings
lead to improved standards of safety for early earth spacecraft. He is
also considered one of the fathers of Nanotechnology; an award named is
his honor has been given since the late twentieth century.
In October 2405 the project approval was received. A rescaled version
of the DELPHI Array began construction. In May 2406 the keel was laid,
and the actual construction on the primary hull began. In June 2406 the
nacelle construction began. August 2406 saw the joinging of primary and
secondary hulls and the installation of the DELPHI array began. In
September 2406 the installation of the remaining communication, navigation
systems and computer core followed.
October 2406 the Warp Drive was tested, followed by finishing the
installation of the rescaled DELPHI array in November, and its calibration
and test in December 2406. In January 2407 the construction was completed
and the ship commissioned for system evaluation as NX-66000 USS Feynman.
The USS TESLA, NCC-66001 was commissioned in July 2407 and lost in August
2408 to warp soliton waves while trying to save a planet. In recognition,
Starfleet ordered the commission of the USS TESLA II, NCC-66101 in September
2412, the ship was commissioned and attached as escort and extension ship to
DS13, in GOLD Fleet, in April 2413.
proposed ship names NCC-66xxx:
USS Feynman USS Heisenberg
USS Fermi USS Hahn
USS Tesla USS Meitner
USS Einstein USS Curie
USS Bohr USS Hawking
Ship Design by Armin Lenz and Kelli Belden
Starfleet Engineering Revision by Armin Lenz, Kelli Belden,
Jeffrey Jenkins, Jeffrey Finocchiaro, Kristopher Kolman
Revised by David S de Lis
[Note: Names of the ships should follow names of Famous Scientists as shown
by the above examples.]
