The present invention relates generally to communications, and more particularly, to communications from a deep space mission to a user on or near the Earth using one or more planetoid satellites.
Several problems exist with prior art systems for communicating between deep space and Earth users. Typically, prior art systems use a radio frequency (RF) medium communication system to send and receive communications between deep space and Earth. These RF systems require extremely large antennas to accommodate both range and bandwidth demands of current communications needs. Conversely, large antennas cannot be easily or cost effectively used in space because of power demands and size and weight demands on the satellites that house the antennas. Furthermore, the antenna's size and weight is increased causing added expense to the launch and maintenance of the communications satellite in orbit. Consequently, the prior art deep space communications cannot be achieved to support the need for extended ranges and bandwidth.
Another problem with prior art deep space communications systems is a lack of continuous data. The lack of continuous data can be caused by a line-of-sight interruption as a result of an eclipse conditions, i.e., a result of a planet, Sun, or moon blocking the data transmission. Another cause of lack of continuous data is the viewing geometry with respect to the Earth receiver and the deep space transmitting source due to the rotation of the Earth.
A further problem with prior art deep space communications systems is the inability to transmit data from the deep regions of space to a centralized Earth receiving station regardless of the Earth's location about the Sun. This problem may be caused by an eclipse situation with respect to the Earth receiver station and the combined effect of Earth rotation.
Accordingly, it is desirable to decrease the antenna size onboard the mission satellite and provide a high bandwidth communication system for communicating between deep space and Earth. It is also desirable to have a deep space communications network that overcomes the above described problems with the prior art by providing a continuous communications network permitting reliable high bandwidth communications between a deep space mission and a user.
The present invention employs at least one satellite (“planetoid”) in an Earth-like orbit about the Sun. The present invention enables high availability, continuous wide band line-of-sight communications between deep space missions and one or more planetoid satellites that can be placed in an orbit about the Sun. The present invention affords significant performance advantages over prior art for deep space communications.
According to one aspect of the present invention, the present invention permits the direct transfer of data between a deep space mission (referred to as the “mission”) and a planetoid. A planetoid is herein described as a satellite placed in an orbit about the Sun. In one embodiment, the planetoid is placed in the Earth's orbit about the Sun. In another embodiment, the planetoid is placed in a plane tilted at an angle from the Earth's ecliptic plane. A method of deep space communication between a deep space location and Earth includes communicating between the planetoid and the deep space location via an optical communications link and communicating between Earth and the planetoid by either an optical or an RF link.
The planetoid includes a communications payload to facilitate the deep space communications. The payload can include an optical transceiver, a RF transmitter, a laser, a telescope, an optical to RF converter, and pointing and control circuitry for the telescope and laser. The planetoid can facilitate a communications link between the mission and the user. The user can be any user including a user on Earth, an airborne or endo-atmospheric user, an exo-atmospheric user, an Earth orbiting satellite, an Earth GEO-stationary or Earth GEO synchronous spacecraft, a high altitude endo/exo-atmospheric platform including an Aerostat, a terrestrial land based, sea based or submersible based fixed or mobile transmitters/receivers, or heavenly bodies or artifact. The mission can be any deep space mission. A planetoid system orbiting the Sun includes a satellite health module for maintaining the planetoid in an orbit, a payload adapted to communicate between a location in deep space and an Earth user, and an interface mechanically and electronically connecting the payload and the satellite health module.
In another aspect of the present invention, the present invention can use a hybrid RF and optical approach to the communications network. In that embodiment, an optical communications link is established between the deep space mission and the planetoid. There are several advantages to using an optical link that overcomes the above described problems with the prior art communications systems such as reduced antenna size and weight and avoiding line-of-sight problems. The planetoid can receive the optical signal and convert it to an RF signal for transmission to the user. In this embodiment, the communications network would work in a similar fashion for communication between the user and the deep space mission, the user can use an RF link to communicate with the planetoid, the planetoid can convert the signal to an optical signal, and transmit it to the deep space mission.
The present invention permits high bandwidth, continuous, and efficient communication between a user and a deep space mission and is intended to provide a communications network for establishing a communications link between any deep space mission and any user. A deep space mission to Jupiter and a user on Earth will be described as one embodiment of the present invention. It will be understood to one of ordinary skill in the art that although the present invention describes a deep space mission location to be Jupiter 150, the present invention is not limited to Jupiter and may apply to communications between any deep space location and any user.
As described above, one likely deep space mission is a mission to Jupiter 150.
One embodiment of the present invention uses a hybrid approach to the communications network. A communications link between the deep space mission 150 and the planetoid 130 or 140 can be established using an optical communications link. The optical beam can be sufficiently sized so as not to complicate beam steering and stabilization by the signal source host at the mission 150. Since, in this embodiment, there are at least two planetoids 130 and 140, the deep space mission can communicate continuously with at least one of the planetoids 130 and 140 without a line-of-sight problem. In other words, there is no eclipse or no time when either the Sun 110, Earth 120, or another planet or moon (not shown) is blocking the communications path between the deep space mission and at least one of the planetoids 130 and 140. A single planetoid 130 or 140 can be used or a plurality of planetoids 130 and 140 can be used. In one embodiment where a plurality of planetoids 130 and 140 is used, the planetoids 130 and 140 are approximately equally spaced from each other in their orbit.
It may also be desirable to convert optical data received from the mission source at Jupiter 150 by planetoid 130 or 140 to an RF medium between the planetoid 130 or 140 and at least one Earth 120 receiving station. Such a concept of operations may be applicable between the planetoid 130 or 140 and Earth 120 in the absence of a cloud-free line-of-sight(s) which otherwise could preclude link closure between both points. In one embodiment the K-band is used in the RF medium. The K-band is a high frequency communications band. RF communications can also use Bandwidth Efficient Modulation (BEM) techniques employed to reduce planetoid relay antenna size, to increase bandwidth with improved forward error encoding of the transmission for a lower bit error rate, and to further reduce transmitter power Effective Isotropic Radiated Power (EIRP).
The communication between the planetoid 130 or 140 and Earth 120 can also be accomplished using an optical link or the planetoid 130 or 140 can determine or can be commanded to select whether to use an optical link or an RF link between the planetoid 130 or 140 and Earth 120 depending upon atmospheric conditions.
In the embodiment shown in
In
When the planetoid 230 orbit plane is tilted off of Earth's ecliptic plane 170, an apparent orbit with respect to the Earth is formed 280. The apparent orbit 280 with respect to the Earth 120 can be thought of as a fixed closed path which resides in a rotating frame where the Earth 120 is also approximately fixed. The rotating non-inertial coordinate frame rotates about an axis normal to the Earth's orbit plane with the Sun 110 at center and at a mean rate equal to the Earth's rotation about the Sun.
In another embodiment, a plurality of planetoids 230 in multiple planes can be deployed consistent with the practice of this invention by placing them in orbits about the Sun 110 such that they follow the same apparent orbit path about the Earth 280 or in nominally concentric paths. If they are equally spaced in a mean sense along a common path each will be in separate planes equally spaced in ascending nodes around the ecliptic plane at a common inclination angle, eccentricity, and argument of perigee of either 270° or 90° from the node. The selection of argument of perigee defines the direction of rotation about the Earth. The relative phasing with respect to these nodes in terms of mean anomaly can be as defined by the conventional Walker code of N/N/N-1. The combination of eccentricity and inclination for near circular apparent Earth orbits can be approximated by the relationship (I=2e) expressed in radians. Nominally concentric orbits result when the inclinations and eccentricities of orbits are not identical.
This embodiment can ensure total Earth 120 global connectivity to mission 150 at any given time. Other variations of this embodiment include, data transfer via planetoid 130 or 140 relayed to at least one Earth satellite 380, to a compatible communications backbone, or to one or a plurality of exo-atmospheric or endo-atmospheric receivers including Aerostats for subsequent relay to, and use by a user. This embodiment is particularly applicable when there are a limited number of Earth 120 receiving stations in preferred geographical locations and to account for Earth rotation which may restrict the viewing geometry between planetoid 130 or 140 and the desired Earth receiving station. If there are multiple Earth receiving stations around the planet, planetoid 130 or 140 can exchange data with a user 120 without regards to Earth rotation.
The satellite functional units 410 include an attitude control subsystem for maintaining attitude control of the planetoid, a power subsystem for maintaining power to the planetoid, a telemetry, tracking, and commanding subsystem for transmitting planetoid telemetry, receiving planetoid commands, and enabling tracking of the planetoid, and a thermal subsystem for maintaining a desired temperature on the planetoid. These subsystems are common on most satellites.
Communications between the mission 150 and the user 120 can operate in the following manner as shown in
Communications between the user 120 and mission 150 can operate in a similar fashion to the above described communications. The user 120 can transmit data using an RF medium to the planetoid 430. Referring to
There can be one, or more than one of any of the subsystems within the payload to accommodate one or multiple optical channels received by optical receiver and demodulator 500. For example, it may be advantageous to have a plurality of optical receivers and demodulators 500 to support a plurality of missions 150. Each planetoid optical receiver and demodulator 500 could then be capable of independent channel modulation and independently steerable by a dedicated pointing and control system 530 to support multiple mission 150 requirements.
In another embodiment, the payload 430 does not convert data from optical to RF signals or from RF to optical signals S620. Instead the planetoid 430 acts as a relay and receives and retransmits the data in the same format to an Earth-orbiting satellite 380.
From the above description, it will be apparent that the invention disclosed herein provides a novel and advantageous system and method of deep space communications.
While the present invention has been discussed with respect to what is presently considered to be the preferred embodiment, it is to be understood that the invention is not limited to the disclosed embodiment. To the contrary, the invention is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.