This Receiver Data Provider reports all
the parameters associated with set up of the receiver.
| Name |
Dimension |
Type |
Description |
| g/T |
GainTempRatio |
Real Number or Text |
g/T = (Receiver Gain)/(System Temperature at the
Receiver). The ratio of the receive antenna gain g to the total
system temperature T is the "figure of merit" for the receiver (in
dB/K). The figure of merit is independent of the point where it is
calculated. However, the gain and system temperature must be
specified at the same point. This is defined by the user as a
constant for the simple receiver. For all other receiver's, the g/T
value is computed for each time step and therefore "N/A" is
reported. |
| Rcvr Model |
Unitless |
Text |
Type of receiver model. |
| Number of Beams |
Unitless |
Real Number or Text |
The number of beams modeled by the receiver. If the
receiver type does not model beams (e.g., Simple Source Receiver),
"N/A" is reported. |
| Gain |
RatioUnit |
Real Number or Text |
Receiver Gain is the antenna gain (in dBi) of the
receiver which is dependent on the antenna type used. For medium
and laser receiver's this value is a constant defined by the user.
For complex and multibeam receiver's, the maximum antenna gain for
the selected antenna type or the receiver is reported. The simple
receiver model assumes an isotropic antenna and therefore reports
the antenna gain as a constant 0.0 dB. |
| Pre-Receive GL |
RatioUnit |
Real Number or Text |
This is the total pre-receive gains and losses
defined by the user for and applied at the front end of the
receiver. |
| Pre-Demod GL |
RatioUnit |
Real Number or Text |
This is the total pre-demodulation gains and losses
defined by the user and applied at the demodulator. |
| System
Temperature |
Unitless |
Text |
The system's inherent noise characteristics which
either the user has defined or has allowed STK to calculate. |
| Constant System Temperature |
Temperature |
Real Number or Text |
Reports out the user selected constant system
temperature value. |
| Receiver
Noise Figure |
RatioUnit |
Real Number or Text |
The noise figure represents the contribution to the
total system noise by the gain stages of the receiver. It can be
thought of as a factor that describes the noise level in a receiver
relative to that in a theoretically perfect receiver. The noise
figure is always greater than 0 dB. |
| Noise Figure |
RatioUnit |
Real Number or Text |
The noise figure represents the contribution to the
total system noise by the gain stages of the receiver. It can be
thought of as a factor that describes the noise level in a receiver
relative to that in a theoretically perfect receiver. The noise
figure is always greater than 0 dB. |
| Transmission Line Loss |
RatioUnit |
Real Number or Text |
The transmission line loss is the loss of the
transmission line between the antenna and receiver. |
| Transmission Line
Temperature |
Temperature |
Real Number or Text |
The transmission line temperature is the physical
temperature of the receiver transmission line. |
| Antenna Noise |
Unitless |
Text |
Noise that the antenna receivers from radiating
bodies within its radiation pattern. Given as a temperature,
antenna noise is a function of the direction in which the antenna
is pointing, its radiation pattern and the state of the surrounding
environment. |
| Antenna Noise - Constant
Temperature |
Temperature |
Real Number or Text |
The antenna noise as a constant temperature,
specified by the user. |
| Antenna Noise - External
File |
Unitless |
Text |
Reports out the filename of the external antenna
noise temperature file. The antenna noise temperature can be given
in a user-specified file that describes antenna noise temperature
(in Kelvin) as a function of the ground elevation angle (in
degrees). |
| Antenna Noise - Use Earth |
Unitless |
Text |
Use the Earth as part of the calculation of the
system temperature for antenna noise. |
| Antenna
Noise - Use Sun |
Unitless |
Text |
Use the Sun when calculating the system temperature
for antenna noise. |
| Antenna Noise - Use
Atmosphere |
Unitless |
Text |
Use the atmosphere when calculating the system
temperature for antenna noise. Available only for a Facility,
Place, or Target. |
| Antenna Noise - Use Rain |
Unitless |
Text |
Use rain when calculating the system temperature
for antenna noise. Available only for a Facility, Place, or
Target. |
| Antenna Noise - Use Cosmic |
Unitless |
Text |
Use the cosmic background noise when calculating
the system temperature for antenna noise. Available only for
Vehicles. |
| Antenna
Noise - Other |
Temperature |
Real Number or Text |
Allows the user to enter noise from other sources
for the calculation of the system temperature for antenna
noise. |
| Polarization |
Unitless |
Text |
Polarization shows which polarization type has been
selected for the antenna. Polarization is a property of an
electromagnetic wave that describes the orientation of the electric
field vector with reference to the antenna's orientation. The three
basic types of polarization are linear, elliptical and circular. In
special cases of linear polarization, the electrical field is
aligned vertically or horizontally with reference to the antenna.
Circular polarization can be right-handed or left-handed. STK
computes the polarization match, which is a quantity between a
transmitter and a receiver based on their polarization types,
positions, and attitudes. If a receiver or transmitter is of a
single-beam type, the Model page for that communications object
allows you to select among several polarization types, and,
depending on the type selected, to specify one or more parameters.
For multi-beam models, polarization is defined in the Modify
Antenna Beam window. |
| Polarization -
Vertical Reference Axis |
Unitless |
Text |
Vertical reference axis specifies the axis (X, Y or
Z) with respect to which the electrical field is oriented. This is
applicable to linear, vertical, horizontal or elliptical
polarization. Otherwise N/A is reported. |
| Polarization - Tilt Angle |
AngleUnit |
Real Number or Text |
Tilt angle is the angle between the vertical
reference axis and the x axis of the coordinate system. This is
applicable to linear or elliptical polarization. Otherwise "N/A" is
reported. |
| Polarization - Axial Ratio |
Unitless |
Real Number or Text |
Axial ratio is the ratio of the major to the minor
axis of the polarization ellipse. This is only applicable to the
elliptical polarization type. |
| Polarization - Cross Pol
Leakage |
RatioUnit |
Real Number or Text |
Whenever STK detects a complete polarization
mismatch between the transmitted signal and the received signal
under ideal conditions, the Cross Polarization Leakage value is
applied to model the less-than-ideal real-world performance. The
value, ranging from -9999.9 dB to -0.001 dB, reflects the
performance of the user's system, where -9999.9 dB represents ideal
conditions (no leakage). |
| Frequency |
Unitless |
Real Number or Text |
This is the frequency that the receiver is tuned to
or operating at. |
| Bandwidth |
Unitless |
Real Number or Text |
The Receiver Bandwidth. |
| Use Spectral
Filter |
Unitless |
Text |
The status of the spectral filter feature. If the
spectral filter is enabled "True" is returned, otherwise "False" is
returned. |
| Filter - Type |
Unitless |
Text |
The type of filter that is selected (e.g.
Butterworth). |
| Filter - Upper Spectral
Limit |
BandwidthUnit |
Real Number or Text |
The selected filter's upper spectral limit. The
filter's upper limit on the power spectrum. The bandwidth limit is
relative to the carrier frequency (the carrier being at zero Hz),
and is specified as a positive value. The upper limit is considered
to be a sharp cutoff point and the spectrum is zero beyond the
limit. |
| Filter - Lower Spectral
Limit |
BandwidthUnit |
Real Number or Text |
The selected filter's lower spectral limit. The
filter's lower limit on the power spectrum. The bandwidth limit is
relative to the carrier frequency and is specified as a positive
value. The lower limit is considered to be a sharp cutoff point and
the spectrum is zero beyond the limit. |
| Filter -
Insertion Loss |
RatioUnit |
Real Number or Text |
The selected filter's insertion loss. This is a
fixed signal attenuation in addition to the spectral loss computed
by the filter's response characteristics. |
| Filter - Order |
Unitless |
Real Number or Text |
The selected filter's order. In general, higher
order filters have sharper roll-offs at the cutoff
frequencies. |
| Filter - -3dB Cutoff
Frequency |
BandwidthUnit |
Real Number or Text |
The selected filter's -3dB (50 percent) filter
attenuation response point. |
| Filter - Ripple |
RatioUnit |
Real Number or Text |
The selected filter's ripple. This value represents
the amount of ripple present in the filter pass and stop
bands. |
| Filter - External Filename |
Unitless |
Text |
The external filter filename, if an external filter
type is selected. |
| Cable Receiver - Excess
Cable Factor |
Unitless |
Real Number or Text |
A multiplier value to the great arc distance that
will be added to the great arc distance. For example, if the great
arc distance between a transmitter and receiver is 1000 km and the
cable between the transmitter and receiver is intended to be four
times the great-arc distance, then the Extra Cable Factor would be
3.0 (resulting in an entire cable length of 4000 km). |
| Cable Receiver -
Propagation Speed Factor |
Unitless |
Real Number or Text |
A scale factor used when calculating the delay
through the transmission medium (range = 0.0 - 1.0), which is
applied to the speed of light to adjust the speed at which EM
propagates through the desired medium. |
| Cable Receiver
- BER |
Unitless |
Real Number or Text |
Bit Error Rate is the probability that a bit is in
error (e.g. a 0 is transmitted but a 1 is received). The BER is the
number of bits in error divided by the total number of bits
sent. |