AU2021104716A4 - Smart integrating & supporting system for satellite communication from mobile devices to public land mobile networks using iot - Google Patents

Abstract

SMART INTEGRATING & SUPPORTING SYSTEM FOR SATELLITE COMMUNICATION FROM MOBILE DEVICES TO PUBLIC LAND MOBILE NETWORKS USING IOT ABSTRACT The present invention is related to smart integrating & supporting system for satellite communication from mobile devices to public land mobile networks using IOT. The objective of present invention is to solve the abnormalities presented in the prior art techniques related to satellite communication from mobile devices to public land mobile networks. 26 DRAWINGS A^ 1. /1--------.-.--.-.---.-.--.-.---.-.---.-.---------.-.- A k ~~NetworkNewr FIGURE 1 27

Description

DRAWINGS

A^ 1. /1--------.-.--.-.---.-.--.-.---.-.---.-.---------.-.-

A k ~~NetworkNewr

FIGURE 1

SMART INTEGRATING & SUPPORTING SYSTEM FOR SATELLITE COMMUNICATION FROM MOBILE DEVICES TO PUBLIC LAND MOBILE NETWORKS USING IOT FIELD OF INVENTION

[001]. The present invention relates to the technical field of satellite

communication.

[002]. The present invention relates to the field of supporting system

for satellite communication from mobile devices.

[003]. Particularly, the present invention relates to the field of secure

communication using satellite and mobile communication network.

[004]. More particularly, the present invention is related to smart

integrating & supporting system for satellite communication

from mobile devices to public land mobile networks using IOT.

BACKGROUND & PRIOR ART

[005]. The subject matter discussed in the background section should

not be assumed to be prior art merely as a result of its mention in the

background section. Similarly, a problem mentioned in the

background section or associated with the subject matter of the

background section should not be assumed to have been previously

recognized in the prior art. The subject matter in the background

section merely represents different approaches, which in-and-of

themselves may also be inventions.

[006]. Some of the work listed herewith:

[007]. 1429474SATELLITE COMMUNICATION METHOD AND

APPARATUS EP - .06.20041nt.Class HO4B 7/212Appl.No

04000663Applicant INMARSAT LTDInventor PHILLIPS KEVIN

PAUL A satellite messaging system has at least one earth station (2)

which sends messages to mobile terminals (6) either on a TDM

channels (T) or a to-mobile messaging channel MF, dependent on

the length of the message. Messages are formatted into a variable

number of frames each containing a variable but equal number of

data packets, so as to make maximum use of the capacity of the

frames. Messages and signalling information are transmitted by the

mobile terminals (6) on a signalling channel (S) comprising frames F

comprising both long (DS) and short (SS) slots, the division between

such slots being controlled by the earth station (2). The mobile

terminals (6) may operate in either an earth station registered mode,

in which they tune to the earth station TDM channel (T) when idle,

or a network registered mode, in which they tune to a network

station TDM channel (NT) when idle. The earth station (2) may

operate in a standard traffic mode, in a low traffic mode, in which

the network station TDM channel NT and signalling channel NS

replace the earth station TDM channel T and signalling channel S, or in a high traffic mode in which the earth station (2) transmits multiple TDM channels (T). The channel spacing between frequency channels used by mobile terminals (6) referenced to the same earth station TDM channel (T) is narrower than that between channels used by mobile terminals (6) referenced to different TDM channels

(T). The earth station (2) transmits using a BPSK modulation

scheme, while the mobile terminals transmit using a pi /2 BPSK

modulation scheme. The earth station (2) stores lists of addresses

which are indexed using a short-form addressing scheme, and can be

modified by the mobile terminals (6). The mobile terminals (6) can

request entry into a sleep mode.

[008]. 2293364SATELLITE COMMUNICATION METHOD AND

APPARATUS CA - 25.11.19991nt.Class HO4Q 7/38Appl.No

2293364Applicant INMARSAT LIMITEDInventor EBVRE, PAUL

ROGER A satellite messaging system has at least one earth station

(2) which sends messages to mobile terminals (6) either on TDM

channels (T) or a to-mobile messaging channel MF, dependent on

the length of the message.

[009]. Messages are formatted into a variable number of frames each

containing a variable but equal number of data packets, so as to

make maximum use of the capacity of the frames. Messages and

signalling information are transmitted by the mobile terminals (6) on

a signalling channel (S) comprising frames F comprising both long

(DS) and short (SS) slots, the division between such slots being

controlled by the earth station (2). The mobile terminals (6) may

operate in either an earth station registered mode, in which they tune

to the earth station TDM channel (T) when idle, or a network

registered mode, in which they tune to a network station TDM

channel (NT) when idle. The earth station (2) may operate in a

standard traffic mode, in a low traffic mode, in which the network

station TDM channel NT and signalling channel NS replace the earth

station TDM channel T and signalling channel S, or in a high traffic

mode in which the earth station (2) transmits multiple TDM channels

(T). The channel spacing between frequency channels used by

mobile terminals (6) referenced to the same earth station TDM

channel (T) is narrower than that between channels used by mobile

terminals (6) referenced to different TDM channels (T). The earth

station (2) transmits using a BPSK modulation scheme, while the mobile terminals transmit using a .pi./2 BPSK modulation scheme.

The earth station (2) stores lists of addresses which are indexed using

a short-form addressing scheme, and can be modified by the mobile

terminals (6). The mobile terminals (6) can request entry into a sleep

mode.

[0010]. WO/1999/060810SATELLITE COMMUNICATION

METHOD AND APPARATUS WO - 25.11.1999 Int.Class H04B

7/185Appl.No PCT/GB1999/001573Applicant NMARSAT

LIMITEDInventor PHILLIPS, Kevin, Paul A satellite messaging

system has at least one earth station (2) which sends messages to

mobile terminals (6) either on TDM channels (T) or a to-mobile

messaging channel MF, dependent on the length of the message.

Messages are formatted into a variable number of frames each

containing a variable but equal number of data packets, so as to

make maximum use of the capacity of the frames.

[0011]. Messages and signalling information are transmitted by the

mobile terminals (6) on a signalling channel (S) comprising frames F

comprising both long (DS) and short (SS) slots, the division between

such slots being controlled by the earth station (2).

[0012]. The mobile terminals (6) may operate in either an earth station

registered mode, in which they tune to the earth station TDM

channel (T) when idle, or a network registered mode, in which they

tune to a network station TDM channel (NT) when idle. The earth

station (2) may operate in a standard traffic mode, in a low traffic

mode, in which the network station TDM channel NT and signalling

channel NS replace the earth station TDM channel T and signalling

channel S, or in a high traffic mode in which the earth station (2)

transmits multiple TDM channels (T). The channel spacing between

frequency channels used by mobile terminals (6) referenced to the

same earth station TDM channel (T) is narrower than that between

channels used by mobile terminals (6) referenced to different TDM

channels (T). The earth station (2) transmits using a BPSK

modulation scheme, while the mobile terminals transmit using a 7/2

BPSK modulation scheme. The earth station (2) stores lists of

addresses which are indexed using a short-form addressing scheme,

and can be modified by the mobile terminals (6). The mobile

terminals (6) can request entry into a sleep mode.

[0013]. 209805828PORTABLE SATELLITE COMMUNICATION

DEVICE CN - 17.12.20191nt.Class HO4B 7/185Appl.No

201921091413.XApplicant GUANGZHOU EHENG

INFORMATION TECHNOLOGY CO., LTD.Inventor WANG

YONGSHENGA portable satellite communication device includes: a

housing; wherein the user information module is used for storing

user information; the satellite communication module is used for

acquiring user information, carrying out identity recognition with a

satellite and carrying out communication; the wireless

communication module is used for communicating with an external

intelligent terminal; and the control module exchanges data with the

satellite communication module and exchanges data with an external

intelligent terminal through the wireless communication module.

The utility model relates toa portable satellite communication device.

The satellite communication module communicates with a satellite;

intelligent terminals such as a mobile phone and a computer can be

accessed; communicationis carried out without special

communication equipment of the system; efficient and convenient

data communication is achieved through simple hardware

configuration, for example, satellite phone dialing, data file uploading and downloading and the like, due to the fact that the coverage area of satellite communication is extremely wide, the system can be used in occasions such as disaster prevention and relief, marine operation, meteorological monitoring and oil exploration, and has the advantages of being suitable for fields, easy to use and the like.

[0014]. 2874327EXTERNAL BATTERY AND SATELLITE

COMMUNICATION TERMINAL EP - 20.05.2015 Int.Class H04B

7/155Appl.No 12879270Applicant MITSUBISHI LECTRIC CORP

Inventor MUKAE HISAYUKI It is aimed to achieve satellite

communication with a popularized mobile phone in a case where a

large number of users communicate at the same time such as in a

case where a disaster strikes and the like.

[0015]. An external battery (20) for charging a mobile phone (10) is

provided with a satellite antenna (22) for performing satellite

communication via a satellite communication channel and a satellite

communication unit (24) which causes the mobile phone (10)

[0016]. to perform the satellite communication via the satellite antenna

(22). The mobile phone (10) and the external battery (20) are

connected with a cable (30) and the like, and thereby a satellite

communication terminal (100) is configured.

[0017]. 2295296MOBILE SATELLITE COMMUNICATIONS

SYSTEM GB - 11.01.19951nt.Class H04M 3/00Appl.No

9423950Applicant INT MARITIME SATELLITE

ORGANIZnventor BAERE JAN DE A communication system

comprises: a plurality of earth stations arranged to communicate with

mobile users via a plurality of satellites; a plurality of gateway

stations for interconnecting terrestrial equipment with the earth

stations; and a store for storing access data for said mobile terminals.

The mobile terminals are divided into first and second categories, the

store retaining corresponding different status information. First and

second different communications channels between said gateway

stations and said earth stations are provided and route control means

selects one of said channels, in dependence upon the category of

mobile terminal, using the system.

[0018]. 2002124898SATELLITE COMMUNICATION GROUND

STATION JP - 26.04.20021nt.Class H04B 7/02Appl.No

2000313612Applicant MITSUBISHI ELECTRIC ORPInventor

TANIGUCHI TERUTAKAPROBLEM TO BE SOLVED: To solve

the roblem that it is necessary to set the same delay time at a

plurality of mobile stations whose delay time is different and one

ground station at the time of communicating by the mobile stations

and the ground station in communication equipment using a time

diversity system, and that it is necessary to provide communication

equipment in the time diversity system corresponding to each delay

time at the time of communicating from the mobile stations whose

delay time is different to the ground station. SOLUTION: In a

satellite communication ground station, a ground station is provided

with a delay time switch device, and the delay time of a delay part 3a

at the reception side is periodically changed when the ground station

is waiting for the reception. The delay time of a mobile station la or

lb is made coincident to the delay time of the delay part 3a of the

ground station so that communication can be performed.

[0019]. 1996340291MOBILE SATELLITE COMMUNICATION

SYSTEM JP - 24.12.19961nt.Class HO4B 7/185Appl.No

1995171364Applicant JISEDAI EISEI SUSHIN SO SYST

KENKYUSHO:KKnventor HARIO KENICHI PURPOSE: To

provide an improved broadcast service of constant quality anywhere

in Japan by transmitting strong broadcast radio waves to a place

where the reception sensitivity distribution of a mobile object

antenna is weak and transmitting weak broadcasting radio waves to

the place where the reception sensitivity distribution is strong by the

use of an on-satellite antenna. CONSTITUTION: A solid line

indicates the strength of the broadcast radio waves transmitted by the

satellite antenna and a broken line indicates the reception sensitivity

of the mobile object antenna. Then, a constant gain is easily obtained

since the range of the latitude of Japan viewed from the satellite

antenna is about three degrees when the orbit of a satellite is a

geostationary orbit for instance and further, since the satellite is

made in a large size, there is a merit that the strength of the broadcast

radio waves to be transmitted can be freely changed for Japan.

[0020]. .5835846MOBILE SATELLITE COMMUNICATION

SYSTEM US - 10.11.19981nt.Class HO4B 17/OOAppl.No

08571126Applicant NTT Mobile Communications Network,

Inc.Inventor Furukawa Kenji A transmission power control method

in a mobile satellite communication system implementing accurate

control of transmission power of a base station by obtaining an

average received signal level at a mobile station at high accuracy.

The mobile station measures an average received signal level

Q.sub.k in a predetermined period (step SP2), and informs the base

station of the average received signal level Q.sub.k and an actual

measuring time T.sub.k (step SP3). The base station calculates a total

measuring time t.sub.k which is the sum total of the actual measuring

time T.sub.k (step SP16), a corrected average received signal level

R.sub.k associated with the average received signal level during the

total measuring time t.sub.k (step SP18), and a measuring error

.DELTA.D.sub.k (step SP17), and controls the transmission power

on the basis of these values (step SP21). Estimating the measuring

error .DELTA.D.sub.k in the total measuring time t.sub.k longer than

the individual actual measuring time T.sub.k makes it possible to reduce the measuring error, thereby implementing highly accurate transmission power control.

[0021]. .Groupings of alternative elements or embodiments of the

invention disclosed herein are not to be construed as limitations.

Each group member can be referred to and claimed individually or in

any combination with other members of the group or other elements

found herein. One or more members of a group can be included in,

[0022]. or deleted from, a group for reasons of convenience and/or

patentability. When any such inclusion or deletion occurs, the

specification is herein deemed to contain the group as modified thus

fulfilling the written description of all Markus groups used in the

appended claims.

[0023]. As used in the description herein and throughout the claims that

follow, the meaning of "a," "an," and "the" includes plural reference

unless the context clearly dictates otherwise. Also, as used in the

description herein, the meaning of "in" includes "in" and "on" unless

the context clearly dictates otherwise.

[0024]. The recitation of ranges of values herein is merely intended to

serve as a shorthand method of referring individually to each separate

value falling within the range. Unless otherwise indicated herein, each

individual value is incorporated into the specification as if it were

individually recited herein. All methods described herein can be

performed in any suitable order unless otherwise indicated herein or

otherwise clearly contradicted by context.

[0025]. The use of any and all examples, or exemplary language (e.g.

"such as") provided with respect to certain embodiments herein is

intended merely to better illuminate the invention and does not pose a

limitation on the scope of the invention otherwise claimed. No

language in the specification should be construed as indicating any

non-claimed element essential to the practice of the invention.

[0026]. The above information disclosed in this Background section is

only for enhancement of understanding of the background of the

invention and therefore it may contain information that does not form

the prior art that is already known in this country to a person of

ordinary skill in the art.

SUMMARY

[0027]. The present invention mainly cures and solves the technical

problems existing in the prior art. In response to these problems, the

present invention provides smart integrating & supporting system for

satellite communication from mobile devices to public land mobile

networks using IOT.

[0028]. As one aspect of the present invention relates to A smart

integrating & supporting system for satellite communication from

mobile devices to public land mobile networks wherein a

communication mobile device uses a first address corresponding to a

first satellite communication standard upon commencement of a

communication session with a satellite resource in a satellite

supporting the first satellite communication standard and a second

satellite communication standard, and subsequently requests a

second address corresponding to the second satellite communication

standard if the satellite resource uses the second satellite

communication standard, wherein the method of communication

comprising steps of: Receiving a satellite code associated with a

mixed communication satellite, the mixed communication satellite

associated with a first satellite communication standard and a second satellite communication standard; Generating, at a first communication mobile device, a first standard-specific code for use with the first satellite communication standard of the mixed communication satellite, the first standard-specific code based at least in part on the satellite code and a first identifier Corresponding to the first satellite communication standard; and communicating with a second communication mobile device in the mixed communication satellite via the first satellite communication standard using the first standard-specific code.

OBJECTIVE OF THE INVENTION

[0029]. The principle objective of the present invention is to provide

smart integrating & supporting system for satellite communication

from mobile devices to public land mobile networks using IOT.

BRIEF DESCRIPTION OF DRAWINGS

[0030]. Further clarify various aspects of some example embodiments of

the present invention, a more particular description of the invention

will be rendered by reference to specific embodiments thereof which

are illustrated in the appended drawings. It is appreciated that these

drawings depict only illustrated embodiments of the invention and are

therefore not to be considered limiting of its scope. The invention will

be described and explained with additional specificity and detail

through the use of the accompanying drawings.

[0031]. In order that the advantages of the present invention will be

easily understood, a detailed description of the invention is discussed

below in conjunction with the appended drawings, which, however,

should not be considered to limit the scope of the invention to the

accompanying drawings, in which:

[0032]. Figure 1 shows an exemplary representation of smart integrating

& supporting system for satellite communication from mobile devices

to public land mobile networks using IOT, according to the present

invention.

DETAIL DESCRIPTION

[0033]. The present invention discloses smart integrating & supporting

system for satellite communication from mobile devices to public land

mobile networks using IOT.

[0034]. Figure 1 shows the exemplary representation of smart

integrating & supporting system for satellite communication from

mobile devices to public land mobile networks using IOT, according

to the present invention.

[0035]. Although the present disclosure has been described with the

purpose of two smart frameworks for providing privacy and protection

in block chain based private transactions using cloud computing

approach, it should be appreciated that the same has been done merely

to illustrate the invention in an exemplary manner and to highlight any

other purpose or function for which explained structures or

configurations could be used and is covered within the scope of the

present disclosure.

[0036]. A smart integrating & supporting system for satellite

communication from mobile devices to public land mobile

networks using IOT is disclosed.

[0037]. A smart integrating & supporting system for satellite

communication from mobile devices to public land mobile

networks wherein a communication mobile device uses a first

address corresponding to a first satellite communication standard

upon commencement of a communication session with a satellite

resource in a satellite supporting the first satellite communication

standard and a second satellite communication standard.

[0038]. A subsequently requests a second address corresponding

to the second satellite communication standard if the satellite

resource uses the second satellite communication standard, wherein

the method of communication comprising steps of: receiving a

satellite code associated with a mixed communication satellite, the

mixed communication satellite associated with a first satellite

communication standard and a second satellite communication

standard.

[0039]. Generating, at a first communication mobile device, a

first standard-specific code for use with the first satellite

communication standard of the mixed communication satellite.

[0040]. The first standard-specific code based at least in part on

the satellite code and a first identifier Corresponding to the first

satellite communication standard.

[0041]. The communicating with a second communication

mobile device is performed in the mixed communication satellite

via the first satellite communication standard using the first

standard-specific code.

[0042]. Then step of Determining a satellite communications

state associated is performed with the diminished communications

throughput, based on the detected at least one satellite

communications metric.

[0043]. The communication mobile device is a smart phone.

[0044]. . The figures and the foregoing description give examples of

embodiments. Those skilled in the art will appreciate that one or

more of the described elements may well be combined into a single

functional element. Alternatively, certain elements may be split into

multiple functional elements. Elements from one embodiment may

be added to another embodiment.

[0045]. For example, order of processes described herein may be

changed and are not limited to the manner described herein.

Moreover, the actions of any block diagram need not be

implemented in the order shown; nor do all of the acts need to be

necessarily performed. Also, those acts that are not dependent on

other acts may be performed in parallel with the other acts. The

scope of embodiments is by no means limited by these specific

examples.

[0046]. Although implementations of the invention have been described

in a language specific to structural features and/or methods, it is to

be understood that the appended claims are not necessarily limited to

the specific features or methods described. Rather, the specific

features and methods are disclosed as examples of implementations

of the invention.

Claims (3)

CLAIMS I/We claim:

1. A smart integrating & supporting system for satellite

communication from mobile devices to public land mobile

networks wherein a communication mobile device uses a first

address corresponding to a first satellite communication

standard upon commencement of a communication session with

a satellite resource in a satellite supporting the first satellite

communication standard and a second satellite communication

standard, and subsequently requests a second address

corresponding to the second satellite communication standard if

the satellite resource uses the second satellite communication

standard, wherein the method of communication comprising

steps of:

Receiving a satellite code associated with a mixed

communication satellite, the mixed communication satellite

associated with a first satellite communication standard and a

second satellite communication standard;

Generating, at a first communication mobile device, a first

standard-specific code for use with the first satellite

communication standard of the mixed communication satellite,

the first standard-specific code based at least in part on the

satellite code and a first identifier Corresponding to the first

satellite communication standard; and

communicating with a second communication mobile device in

the mixed communication satellite via the first satellite

communication standard using the first standard-specific code.

2. The smart integrating & supporting system for satellite

communication from mobile devices to public land mobile networks as claimed in claim 1, wherein Determining a satellite communications state associated with the diminished communications throughput, based on the detected at least one satellite communications metric.

3. The smart integrating & supporting system for satellite

communication from mobile devices to public land mobile

networks as claimed in claim 1, wherein the communication

mobile device is a smart phone.