Research of An Improved Satellite-based Quantum Positioning

System

Wei Fan

1, a

Universty of Rochester, Rochester, U.S

Keywords: Quantum Positioning System, GNSS, TDOA, Acquisition Tracking and pointing.

Abstract: The accuracy of traditional GPS system is limited, and it is liable to be deceived and jammed. The problem

of its application has become increasingly prominent. Based on quantum physics, quantum navigation

technology has the potential to achieve high-precision navigation and positioning services. At present, the

implementation scheme of baseline interferometric satellite-based quantum positioning system proposed by

the United States requires six satellites to achieve positioning, and the cost of the system is high. This paper

presents an improved satellite-based QPS system and describes it systematically. The whole QPS system

includes the establishment of satellite-ground optical link, the acquisition of TDOA by entangled light, the

process of ranging and positioning. Compared with the traditional baseline interferometric satellite-based

QPS system, the number of satellites needed is reduced effectively.

1 INTRODUCTION

Global Navigation Satellite System (GNSS),

represented by GPS, has been widely used, but its

accuracy and security problems are becoming

prominent in current applications. The accuracy of

GPS can only reach meter level, and the GPS signal

is easy to be rewritten and deceived. With the

increasing demand for navigation and positioning

services, the accuracy and security of traditional

navigation systems such as GPS have become one of

the bottleneck of future applications. With the

development of quantum technology, the navigation

system based on quantum technology may become

an important solution. Quantum Positioning System

(QPS) was first proposed by Dr. Giovannetti of

Massachusetts Institute of Technology (MIT) in

2001 in Nature. It is proved that the quantum

entanglement and compression properties can further

improve the positioning accuracy. QPS can not only

break through the limit of traditional positioning

accuracy, but also provide good security in

confidentiality and anti-jamming ability. It may

fundamentally solve the security problem of

transmission and it also breaks the stereotype of

people's thinking in information transmission and

coding. (Giovannetti, V, et.al, 2001; Marks, & Paul,

2014)

QPS can be divided into two categories: passive

quantum positioning system and active quantum

positioning system. Active QPS locates by sending

and receiving quantum signals, and passive QPS

locates by quantum sensor devices. Passive QPS

based on inertial navigation obtains high-precision

magnetic field and gravity field data through cold

atom interference technology. Combining with

traditional geomagnetic navigation and gravity

navigation technology, it achieves high-precision

navigation. The research group of Stanford

University demonstrated the working principle of

atomic interferometric gyroscope based on Sagnac

effect. The British Defense Science and Technology

Laboratory (DSTL), the Landragin Group of the

French Observatory and the Rasel Group of

Germany also carried out relevant research. China

University of Science and Technology, Wuhan

Institute of Physics and Mathematics of Chinese

Academy of Sciences, Tsinghua University and

China Academy of Aerospace Sciences and

Technology, have studied quantum interference

gyroscope, atomic spin gyroscope and nuclear

magnetic resonance gyroscope based on quantum

technology.

In addition to the passive QPS based on inertial

navigation, the active QPS is also an important

development direction. Active QPS uses entangled

light with quantum entanglement to replace

456

Fan, W.

Research of An Improved Satellite-based Quantum Positioning System.

DOI: 10.5220/0008873104560460

In Proceedings of 5th International Conference on Vehicle, Mechanical and Electrical Engineering (ICVMEE 2019), pages 456-460

ISBN: 978-989-758-412-1

electromagnetic wave on the basis of GPS. By

measuring the time difference of arrival (TDOA) of

two interrelated entangled light beams, the distance

between satellite and user and the spatial coordinates

of user are calculated according to the acquired

TDOA. The satellite-based interferometric QPS

proposed by the US Army Research Laboratory,

combined with the traditional satellite positioning

idea and the optical quantum entanglement pulse

interferometric ranging technology, is the first to put

forward the design scheme of the satellite-based

QPS to achieve positioning. It uses satellite to

broadcast quantum signals. The basic structure of

QPS is composed of three baselines which are

composed of two groups of satellites with six known

positions. The satellites are located in two focal

points of a hyperboloid, and the user is at the

intersection point of a hyperboloid consisting of a

hyperboloid. But the disadvantage is that six

satellites with three baselines are needed to

participate in positioning, which is costly.

(Giovannetti, & V, 2004)

Based on the existing active QPS, this paper

improves the implementation scheme of baseline

interferometric quantum positioning system

proposed by Dr. Thomas B. Bahder, U. S. Army

Research Laboratory. An improved QPS based on

three satellites is proposed to locate users. The

number of satellites needed and the complexity of

the system is reduced. The whole process of ranging

and positioning of the improved satellite-based QPS

is analyzed and the system structure is designed.

Firstly, a satellite-ground optical link is established

between the satellite and the ground. The quantum

entangled light emitted by the user equipment and

transmits to the satellite along the satellite-ground

optical link, and then returns to the user through the

reflection of the satellite along the original path. The

TDOA of signal light and reference light is obtained

by pulse matching counting and data fitting with

least square method. Finally, the distance and user

space coordinates are calculated according to the

TDOA simultaneous equations obtained from

entangled light of three satellites. Through the

Acquisition Tracking and Pointing (ATP) system to

achieve the uninterrupted positioning of the user.

The structure of this paper is as follows: Firstly, the

flow of the whole system is explained, including the

establishment of satellite-ground optical link, the

acquisition of TDOA by entangled light, and then

ranging and location solution by simultaneous

equations. (Bahder, T. B, 2004)

2 BASIC PRINCIPLE OF

IMPROVED SATELLITE-

BASED QPS LOCATION

The ranging and positioning process of improved

satellite-based QPS can be divided into three parts:

Firstly, a stable optical link is established between

satellites and the earth, and the positioning are

carried out by using quantum entangled optical

dynamic communication. The establishment of

satellite-to-ground optical link is to provide accurate

optical links for quantum entangled optical signals to

propagate between satellites and users, including

beacon light emission, acquisition, tracking and

aiming. These four sub-processes are realized by

ATP system. Then, based on the quantum entangled

light ranging, according to the established satellite-

ground optical link, the quantum entangled light

dynamic communication is used for ranging and

positioning. Its working process is divided into the

emission and reception of quantum entangled light

and the acquisition of TDOA. Finally, the position is

calculated based on the equations obtained by

TDOA quantum ranging. (Yang, C, et.al, 2010)

Geometric positioning principle is used in

positioning calculation. Two entangled beams of

light emitted by the entangled photon pairs generator

at the user end, one of which arrives at the satellite

along the satellite-ground optical link and reflects

back to the ground from the satellite, then received

by a single photon detector on the user side; the

other light is directly emitted to another single

photon detector on the user side to complete the

emission and reception of entangled photon pairs.

The distance is calculated by using TDOA of two

entangled beams. The user's spatial coordinates are

calculated by three TDOAs obtained from three

satellites.

When the difference of arrival time 



between

satellite n (n=1, 2, 3) and user is obtained, the

distance between satellite and user can be calculated

as 







. Let the space coordinates of

three quantum satellites be





















































and







respectively. The formula of

the relationship between the distance between each

satellite and the user and the coordinates of the

ground user can be obtained: 























































. By measuring

the arrival time difference of entangled light from

the user to three satellites, three formulas of parallel

equations are obtained:

Research of An Improved Satellite-based Quantum Positioning System

457







































































































































































The space coordinates (x, y, z) of the ground user

are obtained. The improved QPS maintains the

satellite-ground optical link between the moving

satellite and the user through the advanced aiming

module, realizes the uninterrupted positioning of the

user.

3 DESIGN OF IMPROVED

SATELLITE-BASED QPS

The establishment of satellite-ground optical link is

realized by ATP system, as shown in Figure 1. The

yellow line represents the path of light propagation

and the red line represents the electrical signal. ATP

system consists of beacon light module, coarse

tracking module, meticulous tracking module and

advanced aiming module. The coarse tracking

module consists of an optical antenna, a turntable, a

coarse tracking detector and a coarse tracking

controller. The meticulous tracking module consists

of a fast reflector, a meticulous tracking detector and

a meticulous tracking controller. (Giovannetti, V,

et.al, 2003)

Figure 1. ATP system schematic diagram.

Satellite terminal and ground terminal transmit

beacon light to each other through their beacon light

module, and use ATP system to capture, track and

aim beacon signal, establish a two-way aiming

satellite-ground light link. Firstly, the satellite end

acts as the emitter of beacon light and the ground

end acts as the capturer. Based on ephemeris

information, the orbit and time period of the satellite

passing over the ground are calculated at the ground

end, and then the turntable in the coarse tracking

module is rotated to point its line of sight to the

uncertain region of the satellite passing over the

user. Subsequently, the optical antenna at the

satellite scans the uncertain area where the user is

located, searches for the beacon light emitted by the

user, realizes rough tracking, and acquisition process.

In the precise tracking stage, FSM first reflects the

up-going beacon light which is output by an optical

antenna and processed by a collimating lens, then

enters the precise tracking detector through the

precise tracking lens of the detector, and forms a

spot on the detector. The precise tracking controller

calculates the output control signal through a certain

control algorithm and controls the FSM to deflect at

a certain angle, so that the beacon light can

accurately track the detector center and achieve the

precise alignment of the incident optical axis and the

optical axis of the main optical antenna. At this

point, the satellite terminal and the ground terminal

are in the tracking state. When two-way tracking is

completed at both ends of the satellite and the user,

the establishment and maintenance of the satellite-

ground optical link can be realized, and the emission

and reception of quantum entangled light can be

carried out in the next step. (Cahill, R. T, 2003)

On the established precisely aligned satellite-

ground optical link, ranging based on quantum

entangled light is the key to the whole QPS. The

TDOA acquisition process for a set of improved

QPS is shown in Figure 2. The yellow line

represents quantum entangled beam, and the red line

represents electrical signal. The process is mainly

completed by four parts: entangled photon pair

generator, ATP system, single photon detector and

data processing unit. (Liao, S. K, et.al, 2017)

Figure 2. The TDOA acquisition process of the improved

QPS.

After the satellite-ground optical link is

established, the user end begins to transmit and

receive quantum entangled light. The entangled

ICVMEE 2019 - 5th International Conference on Vehicle, Mechanical and Electrical Engineering

458

photon pair generator produces correlated signal

light and reference light, in which the signal light is

incident to the advanced sighting mirror. The

advanced sighting module drives the advanced

sighting mirror to adjust an angle by calculating the

instantaneous angle deviation caused by the relative

motion of the satellite and the ground, so as to

compensate the angle deviation of the signal light.

Then the signal light enters the FSM of the precise

tracking module, and reflects it to the mirror of the

coarse tracking module, and then to the optical

antenna, which transmits the signal light to the cone

reflector at the satellite end. The signal light of

entangled photon pair passes through the ground

corner cone reflector and returns to the ground-end

ATP system along the original path. First, through

the optical antenna to enters the mirror of the coarse

tracking module and reflects to the FSM of the

meticulous tracking module, and then incident to the

single photon detector 1. After emitted by the

entangled photon pair generator, the reference light

reflected by the mirror, and be directly received into

the single photon detector 2. (Thon, S. M, et.al, 2009)

4 POSITIONING SOLUTION AND

SIMULATION OF IMPROVED

STAR-BASED QPS

The time difference between the time1 when the

signal light reaches the detector 1 and the time2

when the reference light reaches the detector 2 is

called the arrival time difference Δt. And

multiplying it by the speed of light to obtain the

optical path difference between the signal light and

the reference light, and calculating the distance

between the satellite and the ground user. This paper

proposes a pulse matching count and data fitting

process to obtain the arrival time difference. The

whole process is shown in Figure 3:

Figure 3. Pulse matching measurement process.

A pulse matching count is performed with flow1

by adding different delay values ΔT to the signal of

flow2. When the delay value of flow2  is equal to

, all the pulses on flow1 and flow2 can be matched,

and the matched pulse value reaches the maximum.

Since the second-order correlation function of the

entangled light corresponds to the relationship

between the counting value and the time delay, the

delay  corresponding to its maximum value is the

delayed value  of the entangled light. According to

the corresponding matching counts obtained by

given different delays , the matching counts are

normalized, and then drawn the discrete point curve.

By fitting the value of the second-order correlation

function of the discrete entangled light obtained by

normalization, it is found that the corresponding ΔT

of the maximum value of the function is the actual

arrival time difference  of the entangled light.

Figure 4 is a second-order correlation function

curve of the entangled light obtained by pulse

matching counting at delay time ΔT, where the red

point is a normalized discrete sample point, green

line is the fitted second-order correlation function

curve, and the blue line corresponds to the peak

point coordinate of the fitted curve. The entangled

light Δt obtained by the curve is 



.

(Takenaka, H, et.al, 2017)

5 FIGURE 4 SECOND-ORDER

CORRELATION FUCTION

CURVE

Figure 4. Second-order correlation function curve of

entangled light at different ΔT.

6 CONCLUSION

In this paper, an improved star-based QPS system is

proposed and systematically described. The whole

Research of An Improved Satellite-based Quantum Positioning System

459

QPS system includes: the establishment of the star-

ground optical link, the acquisition of TDOA of the

entangled light, the ranging and positioning solution

process. Compared to the traditional 3-baseline star-

based QPS system, the number of satellites required

is effectively reduced.

REFERENCES

Bahder, T. B. (2004). Quantum positioning system.

Physics.

Cahill, R. T. (2003). Quantum-Foam In-Flow Theory of

Gravity and the Global Positioning System (GPS).

arXiv preprint physics/0309016.

Giovannetti, V, Lloyd, S, & Maccone, L. (2001).

Quantum-enhanced positioning and clock

synchronization. Nature, 412(6845), 417-419.

Giovannetti, V., Lloyd, S., & Maccone, L. (2003).

Quantum positioning system. In Coherence and

Quantum Optics VIII (pp. 303-304). Springer, Boston,

MA.

Giovannetti, & V. (2004). Quantum-enhanced

measurements: beating the standard quantum limit.

Science, 306(5700), 1330-1336.

Liao, S. K., Cai, W. Q., Liu, W. Y., Zhang, L., Li, Y., Ren,

J. G., ... & Li, F. Z. (2017). Satellite-to-ground

quantum key distribution. Nature, 549(7670), 43.

Marks, & Paul. (2014). Quantum positioning system steps

in when gps fails. New Scientist, 222(2969), 19.

Takenaka, H., Carrasco-Casado, A., Fujiwara, M.,

Kitamura, M., Sasaki, M., & Toyoshima, M. (2017).

Satellite-to-ground quantum-limited communication

using a 50-kg-class microsatellite. Nature photonics,

11(8), 502.

Thon, S. M., Rakher, M. T., Kim, H., Gudat, J., Irvine, W.

T., Petroff, P. M., & Bouwmeester, D. (2009). Strong

coupling through optical positioning of a quantum dot

in a photonic crystal cavity. Applied Physics Letters,

94(11), 111115.

Yang, C., Wu, D., & Yu, Y. (2010). The Integration of

GPS and Interferometric Quantum Position System for

High Dynamic Precise Positioning. IEEE.

ICVMEE 2019 - 5th International Conference on Vehicle, Mechanical and Electrical Engineering

460