JEWISH KING JESUS IS COMING AT THE RAPTURE FOR US IN THE CLOUDS-DON'T MISS IT FOR THE WORLD.THE BIBLE TAKEN LITERALLY- WHEN THE PLAIN SENSE MAKES GOOD SENSE-SEEK NO OTHER SENSE-LEST YOU END UP IN NONSENSE.GET SAVED NOW- CALL ON JESUS TODAY.THE ONLY SAVIOR OF THE WHOLE EARTH - NO OTHER. 1 COR 15:23-JESUS THE FIRST FRUITS-CHRISTIANS RAPTURED TO JESUS-FIRST FRUITS OF THE SPIRIT-23 But every man in his own order: Christ the firstfruits; afterward they that are Christ’s at his coming.ROMANS 8:23 And not only they, but ourselves also, which have the firstfruits of the Spirit, even we ourselves groan within ourselves, waiting for the adoption, to wit, the redemption of our body.(THE PRE-TRIB RAPTURE)
HOW THE EUROPEAN UNION WILL CONTROL THE WORLDS ECONOMIES BY A SUPER COMPUTER AND A MICROCHIP IMPLANT UNDER YOUR SKIN.
FINALLY THE EUROPEAN UNION IS TALKING ABOUT HAVING THEIR OWN ARMY.AND IT MUST HAPPEN.
REVELATION 19:16-21
16
And he hath on his vesture and on his thigh a name written, King Of
Kings, And Lord Of Lords.(JESUS RETURNG TO EARTH LITERALLY ON A WHITE
HORSE WITH THE RAPTURED CHRISTIANS 7 YEARS EARLIER)
17 And I saw an
angel standing in the sun; and he cried with a loud voice, saying to all
the fowls that fly in the midst of heaven, Come and gather yourselves
together unto the supper of the great God;
18 That ye may eat the
flesh of kings, and the flesh of captains, and the flesh of mighty men,
and the flesh of horses, and of them that sit on them, and the flesh of
all men, both free and bond, both small and great.(2ND TIME GOD-JESUS
TELLS THE 500 MILLION MIGRATING BIRDS TO GET READY TO EAT HUMAN
FLESH.THE FIRST TIME WAS WHEN GOD TOLD THE 500 MILLION MIGRATING
BIRDS-TO EAT RUSSIA,GERMAN,ARAB, MUSLIM BODIES FOR 7 MONTHS IN EZEK 38 @
39.
19 And I saw the beast,(E.U WORLD LEADER) and the kings of the
earth, and their armies,(HERE IT SAYS THE E.U WILL HAVE ITS OWN ARMY)
gathered together to make war against him that sat on the horse, (JESUS)
and against his army.(RAPTURED CHRISTIANS)
20 And the beast (E.U
WORLD LEADER) was taken, and with him the false prophet (POPE FRANCIS)
that wrought miracles before him, with which he deceived them that had
received the mark of the beast, and them that worshipped his image.
These both were cast alive into a lake of fire burning with brimstone.
21
And the remnant were slain with the sword of him that sat upon the
horse, which sword proceeded out of his mouth: and all the fowls were
filled with their flesh.
Zephaniah 2:1-15
1 Gather together, yes, gather,O shameless nation,
2
before the decree takes effect[a] -before the day passes away like
chaff—before there comes upon you the burning anger of the Lord, before
there comes upon you the day of the anger of the Lord.
3 Seek the
Lord, all you humble of the land, who do his just commands;[b] seek
righteousness; seek humility; perhaps you may be hidden on the day of
the anger of the Lord.
4 For Gaza shall be deserted, and Ashkelon
shall become a desolation; Ashdod's people shall be driven out at noon,
and Ekron shall be uprooted.
5 Woe to you inhabitants of the
seacoast, you nation of the Cherethites! The word of the Lord is against
you, O Canaan, land of the Philistines; and I will destroy you until no
inhabitant is left.
6 And you, O seacoast, shall be pastures, with meadows[c] for shepherds and folds for flocks.
7
The seacoast shall become the possession of the remnant of the house of
Judah, on which they shall graze, and in the houses of Ashkelon they
shall lie down at evening. For the Lord their God will be mindful of
them and restore their fortunes.
8 “I have heard the taunts of Moab
(JORDAN) and the revilings of the Ammonites, how they have taunted my
people and made boasts against their territory.
9 Therefore, as I
live,” declares the Lord of hosts, the God of Israel, Moab shall become
like Sodom, and the Ammonites like Gomorrah, a land possessed by nettles
and salt pits, and a waste forever.The remnant of my people shall
plunder them, and the survivors of my nation shall possess them.”
10 This shall be their lot in return for their pride, because they taunted and boasted against the people of the Lord of hosts.
11
The Lord will be awesome against them; for he will famish all the gods
of the earth, and to him shall bow down, each in its place, all the
lands of the nations.
12 You also, O Cushites, shall be slain by my sword.
13
And he will stretch out his hand against the north and destroy
Assyria,(SYRIA) and he will make Nineveh a desolation, a dry waste like
the desert.
14 Herds shall lie down in her midst, all kinds of
beasts;[d] even the owl and the hedgehog[e] shall lodge in her
capitals; a voice shall hoot in the window; devastation will be on the
threshold; for her cedar work will be laid bare.
15 This is the
exultant city that lived securely, that said in her heart, “I am, and
there is no one else.” What a desolation she has become, a lair for wild
beasts! Everyone who passes by her hisses and shakes his fist.Sa'ar: No
free meals; talks possible if more hostages freed Israel halts aid into
Gaza, citing Hamas refusal to extend first phase of truce
Footnotes-a
-Zephaniah 2:2 Hebrew gives birth, b-Zephaniah 2:3 Or who carry out his
judgment, c-Zephaniah 2:6 Or caves, d-Zephaniah 2:14 Hebrew beasts of
every nation, e-Zephaniah 2:14 The identity of the animals rendered owl
and hedgehog is uncertain
DANIEL 2:37-45
37 Thou, O king, art a king of kings: for the God of heaven hath given thee a kingdom, power, and strength, and glory.
38
And wheresoever the children of men dwell, the beasts of the field and
the fowls of the heaven hath he given into thine hand, and hath made
thee ruler over them all. Thou art this head of gold.
39 And after
thee shall arise another kingdom inferior to thee, and another third
kingdom of brass, which shall bear rule over all the earth.
40 And
the fourth kingdom shall be strong as iron: forasmuch as iron breaketh
in pieces and subdueth all things: and as iron that breaketh all these,
shall it break in pieces and bruise.
41 And whereas thou sawest the
feet and toes, part of potters' clay, and part of iron, the kingdom
shall be divided; but there shall be in it of the strength of the iron,
forasmuch as thou sawest the iron mixed with miry clay.
42 And as the toes of the feet were part of iron, and part of clay, so the kingdom shall be partly strong, and partly broken.
43
And whereas thou sawest iron mixed with miry clay, they shall mingle
themselves with the seed of men: but they shall not cleave one to
another, even as iron is not mixed with clay.
44 And in the days of
these kings shall the God of heaven set up a kingdom, which shall never
be destroyed: and the kingdom shall not be left to other people, but it
shall break in pieces and consume all these kingdoms, and it shall stand
for ever.
45 Forasmuch as thou sawest that the stone was cut out of
the mountain without hands, and that it brake in pieces the iron, the
brass, the clay, the silver, and the gold; the great God hath made known
to the king what shall come to pass hereafter: and the dream is
certain, and the interpretation thereof sure.
DANIEL 7:17-26
17 These great beasts, which are four, are four kings, which shall arise out of the earth.
18 But the saints of the most High shall take the kingdom, and possess the kingdom for ever, even for ever and ever.
19
Then I would know the truth of the fourth beast, which was diverse from
all the others, exceeding dreadful, whose teeth were of iron, and his
nails of brass; which devoured, brake in pieces, and stamped the residue
with his feet;
20 And of the ten horns that were in his head, and of
the other which came up, and before whom three fell; even of that horn
that had eyes, and a mouth that spake very great things, whose look was
more stout than his fellows.
21 I beheld, and the same horn made war with the saints, and prevailed against them;
22
Until the Ancient of days came, and judgment was given to the saints of
the most High; and the time came that the saints possessed the kingdom.
23
Thus he said, The fourth beast shall be the fourth kingdom upon earth,
which shall be diverse from all kingdoms, and shall devour the whole
earth, and shall tread it down, and break it in pieces.
24 And the
ten horns out of this kingdom are ten kings that shall arise: and
another shall rise after them; and he shall be diverse from the first,
and he shall subdue three kings.
25 And he shall speak great words
against the most High, and shall wear out the saints of the most High,
and think to change times and laws: and they shall be given into his
hand until a time and times and the dividing of time.
26 But the judgment shall sit, and they shall take away his dominion, to consume and to destroy it unto the end.
THE WORLD IN 10 WORLD TRADE BLOCS LEAD BY THE EUROPEAN UNION THE WORLD LEADER, NOT AMERICA.I PREDICT.
THE EUROPEAN UNION AND REVIVED ROMAN WORLD GOVERNMENT
DANIEL 2:31-33,36-43, DAN 7:3-8,17
First From Daniel Chapter 2
1 EGYPT
2 ASSYRIA
3 BABYLON (HEAD OF GOLD) DAN 2:31-32,36-38, DAN 1:1
4 MEDO-PERSIANS (CHEST & ARMS OF SILVER) DAN 2:32,39, DAN 9:1
5 GREECE (WAIST & HIPS OF BRONZE) DAN 2:32,39, DAN 11:2
6 ROME (2 LEGS OF IRON) DAN 2:33,40, ROM 1:6
7 REVIVED ROME (EU) (FEET IRON & CLAY) DAN 2:33,41-43,10 TOES
Now From Daniel Chapter 7
1 EGYPT
2 ASSYRIA
3 BABYLON (LION WITH EAGLES WINGS) DAN 7:4, DAN 1:1
4 MEDO-PERSIANS (BEAR ON HIND LEGS) DAN 7:5, DAN 9:1
5 GREECE (LEOPARD 4 WINGS, 4 HEADS) DAN 7:6, DAN 11:2
6 ROME (HUGE IRON TEETH) DAN 7:7 (10 HORNS), ROM 1:6
7 REVIVED ROME (EU) DAN 7:8,19-20,23-25 10 HORNS, 10 KINGS
REV
17:9,12, 10 HORNS, 10 KINGS, 7 HILLS ROME. REV 13:1 BEAST WITH 7 HEADS.
THE E.U LEADER OF WORLD GOVERNMENT DAN 2:40-45, 7:7-8,23-25,27, 8:23,
REV 13:3,7,8,12,14,16
REVELATION 17:10-12
10 And there are
seven kings (7TH WORLD EMPIRE IN HISTORY) five are fallen, (EGYPT,
ASSYRIA, BABYLON,:MEDO-PERSIAN,GREECE and one is,(IN POWER IN JOHNS
DAY-ROME) and the other is not yet come; and when he
cometh,(FUTURE-REVIVED ROMAN EMPIRE-EUROPEAN UNION TODAY) he must
continue a short space.(7 YEARS OF WORLD DOMINATION-BUT 3 1/2 YEARS OF
NEW WORLD ORDER OR ONE WORLD GOVERNMENT)
12 And the ten horns (10
WORLD TRADE BLOCS OR REGIONS) which thou sawest are ten kings, which
have received no kingdom as yet; but receive power as kings one hour
with the beast.
REVELATION 17:12-13
12 And the ten horns (10
WORLD TRADE BLOCS-NATIONS) which thou sawest are ten kings, which have
received no kingdom as yet; but receive power as kings one hour with the
beast.
13 These have one mind,(WORLD SOCIALISM) and shall give their power and strength unto the beast.
We
shall have World Government, whether or not we like it. The only
question is whether World Government will be achieved by conquest or
consent.James Paul Warburg appearing before the Senate on 7th February
1950
Like a famous WWII Belgian General,Paul Henry Spock said in
1957:We need no commission, we have already too many. What we need is a
man who is great enough to be able to keep all the people in subjection
to himself and to lift us out of the economic bog into which we threaten
to sink. Send us such a man. Be he a god or a devil, we will accept
him.And today, sadly, the world is indeed ready for such a man.
DICK
MORRIS-This truly creates a global economic system. From now on, don’t
look to Washington for the rule making, look to Brussels.
THE CLUB OF ROME FOUNDER AURELIO PECCEI WANTS THE WORLD IN 10 REGIONAL TRADING BLOCKS.
REVELATION 16:1-2
1
And I heard a great voice out of the temple saying to the seven angels,
Go your ways, and pour out the vials of the wrath of God upon the
earth.
2 And the first went, and poured out his vial upon the earth;
and there fell a noisome and grievous sore upon the men which had the
mark of the beast, and upon them which worshipped his image.
REVELATION 13:16-18
16
And he(FALSE POPE) causeth all, both small and great, rich and poor,
free and bond, (SLAVE) to receive a mark in their right hand, or in
their foreheads:(CHIP IMPLANT)
17 And that no man might buy or sell, save he that had the mark, or the name of the beast, or the number of his name.
18
Here is wisdom. Let him that hath understanding count the number of the
beast: for it is the number of a man; and his number is Six hundred
threescore and six.(6-6-6) A NUMBER SYSTEM
I KNOW THIS MARK WILL
BE A MICROCHIP IMPLANT UNDER THE SKIN. LETS LOOK UP WHAT THE WORD MARK
SAYS IN REVELATION 13:16-18, 14:9,11, 15:2, 16:2, 19:20, 20:4-ALL THESE
VERSES FROM THE BOOK OF REVELATION SPEAK OF THIS DICTATORS MARK. NOW
LETS SEE WHAT IT MEANS FROM STRONGS EXAUSTIVE CONCORDANCE OF THE BIBLE.
UNDER MARK PAGE 684.MARK UNDER MARK. THE OLD TESTAMENT IS UNDER HEBREW
AND THE NEW TESTAMENT IS UNDER GREEK. SO WHEN WE LOOK UNDER REVELATION
13:16-17 WE SEE IT IS UNDER GREEK, SO WE GO TO GREEK IN THE BACK SECTION
AND GO TO 5480 TO SEE WHAT IT SAYS THIS MARK WOULD BE. SO LETS GET TO
IT.MARK IN STRONGS GREEK 5480 XAPAYUA CHARAGMA, KHAR-AG-MAH: FROM THE
SAME AS 5482: A SCRATCH OR ETCHING, I.E STAMP (AS A BADGE OF SERVITUDE),
OR SCULPTURED FIGURE-(STATUE):-GRAVEN, MARK FROM 5482 XAPAE CHARAX,
KHAR-AX; FROM XAPAOOW CHARASSO (TO SHARPEN TO A POINT; AKIN TO 1125
THROUGH THE IDEA OF SCRATCHING); A STAKE, I.E (BYIMPL.) A PALISADE OR
RAMPART (MILITARY MOUND FOR CIRCUMVALLATION IN A SIEGE): - TRENCH FROM
1125 YPAPOE GRAPHO, GRAF-0; A PRIM. VERB; TO "GRAVE", ESPEC. TO WRITE;
FIG. TO DESCRIBE:-DESCRIBE, WRITE (-ING, -TEN).G5516-GO TO G4742-666 -
STRONGS NT 4742: στίγμα - στίγμα, στιγματος, τό (from στίζω to prick;
(cf. Latinstimulus, etc.; German stechen, English stick, sting, etc.;
Curtius, § 226)), a mark pricked in or branded upon the body. According
to ancient oriental usage, slaves and soldiers bore the name or stamp of
their master or commander branded or pricked (cut) into their bodies to
indicate what master or general they belonged to, and there were even
some devotees who stamped themselves in this way with the token of their
gods (cf. Deyling, Observations, iii., p. 423ff); hence, τά στίγματα
τοῦ (κυρίου so Rec.) Ἰησοῦ, the marks of (the Lord) Jesus, which Paul in
Galatians 6:17 says he bears branded on his body, are the traces left
there by the perils, hardships, imprisonments, scourgings, endured by
him for the cause of Christ, and which mark him as Christ's faithful and
approved votary, servant, soldier (see Lightfoots Commentary on
Galatians, the passage cited). (Herodotus 7, 233; Aristotle, Aelian,
Plutarch, Lcian, others.)
THE INVENTOR OF THE MICROCHIP IMPLANT-CARL SANDERS MICROCHIP ENGINEER LEADER
https://www.youtube.com/watch?v=rgH9D6n4ZWo
THE MICROCHIP IMPLANT IN YOUR RIGHT HAND OR FOREHEAD.
LEVETICUS 19.28
Ye shall not make any cuttings in your flesh for the dead, nor print any marks upon you: I am the LORD.
HERES WHAT THE WORLD WOULD LOOK LIKE (SINCE THERE WILL BE WORLD GOVERNMENT IN THE FUTURE)-UPDATED VERSION
01 CANADA, U.S.A, MEXICO
02 EUROPEAN UNION,WESTERN EUROPE
03 JAPAN
04 AUSTRALIA,NEW ZEALAND, S AFRICA, ISRAEL AND PACIFIC ISLANDS
05 EASTERN EUROPE
06 SOUTHERN, CENTRAL AND LATIN AMERICAS
07 NORTH AFRICA, AND MIDEAST (MOSLEMS)
08 CENTRAL AFRICA
09 SOUTH AND SOUTHEAST ASIA
10 CENTRAL ASIA
THE
CLUB OF ROME WANTS A WORLD CHARISMATIC DICTATOR (EITHER RELIGIOUS,
POLITICAL OR SCIENTIFICAL) TO HEAD THIS WORLD GOVERNMENT. REV 13:3,7-8,
DAN 7:23-24
WORLD POWERS IN THE END TIME
NORTH - RUSSIA EZEK 38:1-2, 39:1-2
SOUTH - EGYPT DAN 11:42
EAST - CHINA DAN 11:44,REV 16:12
WEST - EUROPEAN UNION DAN 7:23-24 (NOT THE U.S.A)
http://israel7777777.blogspot.ca/2012/03/10-world-trade-blocs-one-world.html
http://israndjer.blogspot.ca/2006/09/how-eu-takes-world-control.html
http://israndjer.blogspot.ca/2012/05/one-world-religion-crislam.html
FINALLY THE EUROPEAN UNION IS TALKING ABOUT HAVING THEIR OWN ARMY.AND IT MUST HAPPEN.
REVELATION 19:16-21
16
And he hath on his vesture and on his thigh a name written, King Of
Kings, And Lord Of Lords.(JESUS RETURNG TO EARTH LITERALLY ON A WHITE
HORSE WITH THE RAPTURED CHRISTIANS 7 YEARS EARLIER)
17 And I saw an
angel standing in the sun; and he cried with a loud voice, saying to all
the fowls that fly in the midst of heaven, Come and gather yourselves
together unto the supper of the great God;
18 That ye may eat the
flesh of kings, and the flesh of captains, and the flesh of mighty men,
and the flesh of horses, and of them that sit on them, and the flesh of
all men, both free and bond, both small and great.(2ND TIME GOD-JESUS
TELLS THE 500 MILLION MIGRATING BIRDS TO GET READY TO EAT HUMAN
FLESH.THE FIRST TIME WAS WHEN GOD TOLD THE 500 MILLION MIGRATING
BIRDS-TO EAT RUSSIA,GERMAN,ARAB, MUSLIM BODIES FOR 7 MONTHS IN EZEK 38 @
39.
19 And I saw the beast,(E.U WORLD LEADER) and the kings of the
earth, and their armies,(HERE IT SAYS THE E.U WILL HAVE ITS OWN ARMY)
gathered together to make war against him that sat on the horse, (JESUS)
and against his army.(RAPTURED CHRISTIANS)
20 And the beast (E.U
WORLD LEADER) was taken, and with him the false prophet (POPE FRANCIS)
that wrought miracles before him, with which he deceived them that had
received the mark of the beast, and them that worshipped his image.
These both were cast alive into a lake of fire burning with brimstone.
21
And the remnant were slain with the sword of him that sat upon the
horse, which sword proceeded out of his mouth: and all the fowls were
filled with their flesh.
COUNCIL FOR EUROPE ON DEFENCE
https://defence-industry-space.ec.europa.eu/document/download/6d6f889c-e58d-4caa-8f3b-8b93154fe206_en?filename=SAFE%20Regulation.pdf
HERES
HOW THE E.U WILL KEEP TRACK OF EVERY ONE OF EARTHS POPULATION. AND YOUR
MICROCHIP IMPLANT IMFORMATION WILL GO DIRECTLY INTO THIS SUPER
COMPUTER. YOU DON'T THINK THIS FUTURE E.U DICTATOR CAN NOT KEEP TRACK OF
EVERY ONE ON EARTH. 24 HOURS A DAY. AND WITH AI THE E.U LEADER CAN DO
FAKE MIRACLES AND WONDERS. NO WONDER ALL ON EARTH NOT SAVED WILL BE
DECIEVED TO WORSHIP THIS EU FUTURE WORLD LEADER.AND THE MICROCHIP
IMPLANT WILL BE THE NEW CASHLESS SOCIETY MONEY. SO WE SEE THE EU
CONTROLLING ALL THE WORLDS ECONOMIES.
EU RULES FOR SUPER COMPUTING
https://www.eurohpc-ju.europa.eu/european-commission-proposes-amendment-eurohpc-regulation-support-gigafactories-and-include-quantum-2025-07-16_en
JULICH SUPER COMPUTING.
https://www.fz-juelich.de/en/ias/jsc
JUPITER- https://www.fz-juelich.de/en/ias/jsc/jupiter
Europe bets on supercomputer to catch up in AI race.
Jülich,
Germany, Sept 5 (AFP) Sep 05, 2025-Europe's fastest supercomputer
Jupiter was inaugurated Friday in Germany with Chancellor Friedrich Merz
saying it could help the continent catch up in the global artificial
intelligence race."We in Germany, and we in Europe, have every
opportunity to catch up and then keep pace" with AI pioneers the United
States and China, said Merz.Here is all you need to know about the
system, which boasts the power of around one million smartphones.- What
is the Jupiter supercomputer? -Based at Juelich Supercomputing Centre in
western Germany, it is Europe's first "exascale" supercomputer --
meaning it will be able to perform at least one quintillion (or one
billion billion) calculations per second.The United States already has
three such computers, all operated by the Department of Energy.Jupiter
is housed in a centre covering some 3,600 metres (38,000 square feet) --
about half the size of a football pitch -- containing racks of
processors, and packed with about 24,000 Nvidia chips, which are
favoured by the AI industry.Half the 500 million euros ($580 million) to
develop and run the system over the next few years comes from the
European Union and the rest from Germany.Its vast computing power can be
accessed by researchers across numerous fields as well as companies for
purposes such as training AI models."Jupiter is a leap forward in the
performance of computing in Europe," Thomas Lippert, head of the Juelich
centre, told AFP, adding that it was 20 times more powerful than any
other computer in Germany.- How can it help Europe in the AI race?
-Lippert said Jupiter is the first supercomputer that could be
considered internationally competitive for training AI models in Europe,
which has lagged behind the United States and China in the
sector.According to a Stanford University report this year, US-based
institutions produced 40 "notable" AI models -- meaning those regarded
as particularly influential -- in 2024, compared to 15 for China and
just three for Europe.In a speech at the inauguration in Juelich, Merz
conceded that the United States and China were currently in a
"neck-and-neck race" for dominance in the AI field.But he insisted that
Europe could make up lost ground -- and that it was crucial the
continent do so."In Germany and in Europe as a whole, we need sovereign
computing capacities that are on a par with our international
competitors," Merz said."This is a question of competitiveness as well
as the security of our country."Jupiter was built by a consortium
consisting of Eviden, a subsidiary of French tech giant Atos, and German
group ParTec.But, with Nvidia chips powering the machine, it is still
heavily reliant on US technology.The dominance of the US tech sector has
become a source of growing concern as US-European relations have
soured.- What else can the computer be used for? -Jupiter has a wide
range of other potential uses beyond training AI models.Researchers want
to use it to create more detailed, long-term climate forecasts that
they hope can more accurately predict the likelihood of extreme weather
events.Le Roux said that current models can simulate climate change over
the next decade."With Jupiter, scientists believe they will be able to
forecast up to at least 30 years, and in some models, perhaps even up to
100 years," he added.Others hope to simulate processes in the brain
more realistically, research that could be useful in areas such as
developing drugs to combat diseases like Alzheimer's.It can also be used
for research related to the clean energy transition, for instance by
simulating air flows around wind turbines to optimise their design.-
Does Jupiter consume a lot of energy? -Yes, Jupiter will require on
average around 11 megawatts of power, according to estimates --
equivalent to the energy used to power thousands of homes or a small
industrial plant.But its operators insist that Jupiter is the most
energy-efficient among the fastest computer systems in the world.It uses
the latest, most energy-efficient hardware, has water-cooling systems
and the waste heat that it generates will be used to heat nearby
buildings, according to the Juelich centre.sr/fz/lth
Press release 5 September 2025European High-Performance Computing Joint Undertaking-JUPITER: Launching Europe's Exascale Era
JUPITER,
Europe’s first exascale supercomputer, was inaugurated today in Jülich,
Germany by Chancellor Friedrich Merz & European Commissioner
Ekaterina Zaharieva. The inauguration marks the beginning of a new era
for European supercomputing.The event was also attended by high-ranking
guests from politics, science, and industry including Hendrik Wüst,
Minister-President of North Rhine-Westphalia; Roberto Viola,
Director-General for Communication Networks, Content and Technology, at
the European Commission (DG CNECT); Rafal Duczmal, Chair of the EuroHPC
Joint Undertaking (EuroHPC JU) Governing Board; and Anders Jensen, the
EuroHPC JU Executive Director.Designed by the Jülich Supercomputing
Centre (JSC) at Forschungszentrum Jülich in collaboration with EuroHPC
JU and procured by EuroHPC Joint Undertaking, JUPITER stands as the
first European supercomputer capable of performing one exaflop, which is
equivalent to one billion times one billion calculations per second (1
ExaFLOP/s). It is also the most powerful system in Europe, combining
outstanding performance with exceptional energy efficiency. It would
take every person on Earth performing one calculation per second over
four years to match what JUPITER can accomplish in a single second. This
next-generation supercomputer represents a major leap in European
technology and its unprecedented computing capacity will have a
substantial impact on scientific progress across Europe. It will bolster
European competitiveness and technological sovereignty, while pushing
the frontiers of scientific simulations and facilitate the development
of advanced AI models for socially relevant applications, ranging from
medicine and highly precise climate and weather forecasts to the
optimisation of sustainable energy systems and multilingual European
language models.JUPITER will accelerate innovation and scientific
discovery across Europe with access open to all users via the EuroHPC
access calls. The allocation of the computing resources is jointly
managed by the EuroHPC JU and the Gauss Centre for Supercomputing. This
access will follow the successful rollout of the JUPITER Research and
Early Access Program (JUREAP), which in recent months empowered more
than 30 lighthouse projects, 15 of which were selected by EuroHPC JU, to
explore and optimise their applications on the system. Through early
access to JUPITER’s cutting-edge infrastructure, European researchers
were able to push the limits of performance, experiment with
next-generation hardware and software technologies, and fine-tune their
codes for peak efficiency. The participating projects covered a wide
range of domains from chemical sciences and computational physics to
earth system modelling, engineering, and large-scale AI ensuring that
JUPITER will deliver transformative impact across European science and
industry from day one.Anders Jensen, EuroHPC JU Executive Director
stated:" With JUPITER, Europe is entering the exascale era, unlocking
unprecedented computing power to drive scientific discovery, industrial
innovation, and technological sovereignty. I look forward to see the
first wave of exascale applications and the breakthroughs they will
bring. "Prof. Dr. Dr. Thomas Lippert, Director of the Jülich
Supercomputing Centre added:“After a decade of intensive innovation
efforts, we have collaboratively developed a system that not only sets
new standards in computational performance but will fundamentally change
scientific research across numerous fields. The most complex AI models
can now be trained and applied – something that was not possible without
JUPITER.” Ceremonial inauguration of the JUPITER Exascale
Supercomputer-Based on Eviden’s latest BullSequana XH3000 architecture,
JUPITER Booster is equipped with approximately 24,000 NVIDIA GH200 Grace
Hopper Superchips, specifically optimised for computationally intensive
simulations and the training of AI models. This cutting-edge
architecture enables JUPITER to achieve up to 80 ExaFLOP/s AI
performance, with 8 bit precision and sparse matrices, making it one of
the world’s fastest systems for Artificial Intelligence.Composed of
highly energy-efficient partitions, JUPITER is also setting new
standards in sustainability and stands out as one of the most
energy-efficient systems in the world. Thanks to its highly efficient
warm-water cooling system, the supercomputer is designed to reuse the
heat it generates during operation to heat buildings. For this purpose,
it will be integrated into the heating network of the Jülich
campus.JUPITER, short for “Joint Undertaking Pioneer for Innovative and
Transformative Exascale Research”, is fully owned and co-funded half by
the European High Performance Computing Joint Undertaking (EuroHPC JU).
The remaining half is funded equally by the German Federal Ministry of
Research, Technology and Space (BMFTR, formerly BMBF) and the German
Ministry of Culture and Science of the State of North Rhine-Westphalia
(MKW NRW).Next steps-Later this year, JUPITER will be complemented by
the JUPITER AI Factory (JAIF) , selected in March 2025 as part of the
EuroHPC JU’s initiative to establish AI Factories across Europe, to
support industry, particularly start-ups and small and medium-sized
enterprises (SMEs), to harness its power to develop powerful, secure AI
applications that conform with data protection
requirements.Background-The EuroHPC JU is a legal and funding entity
that brings together the European Union and participating countries to
coordinate efforts and pool resources with the objective of making
Europe a world leader in supercomputing.To equip Europe with a
cutting-edge supercomputing infrastructure, the EuroHPC JU has already
procured 11 supercomputers, distributed across Europe. Three of these
EuroHPC supercomputers are now ranked among the world’s top 10 most
powerful supercomputers: JUPITER in Germany ranks at 4, becoming
Europe’s new fastest supercomputer along with LUMI in Finland (9th
place), Leonardo in Italy (10th place).European scientists and users
from the public sector and industry can benefit from EuroHPC
supercomputers via the EuroHPC Access Calls no matter where in Europe
they are located, to advance science and support the development of a
wide range of applications with industrial, scientific and societal
relevance for Europe.Currently, the EuroHPC JU is also overseeing the
implementation of 13 AI factories across Europe that offer free,
customised support to SMEs and startups, JAIF being one them.
Additionally, the EuroHPC JU is deploying a European Quantum Computing
infrastructure, integrating diverse European quantum computing
technologies with existing supercomputers.The EuroHPC JU also funds
research and innovation projects to develop a full European
supercomputing supply chain, from processors and software to
applications to be run on these
Press release10 July 2025European High-Performance Computing Joint Undertaking-
EuroHPC
JU Signs Procurement Contract for Arrhenius Supercomputer-The EuroHPC
Joint Undertaking (EuroHPC JU), together with the National Academic
Infrastructure for Supercomputing in Sweden (NAISS), has signed a
procurement contract for Arrhenius with the selected vendor, HPE.
Arrhenius will be a mid-range supercomputer capable of executing over 60
petaflops, equivalent to 60 million billion operations per second,
enabling the most advanced simulations in science and technology.
Arrhenius will drive breakthroughs in areas like drug discovery, new
materials design, and climate change mitigation while also powering
applications in Artificial Intelligence (AI), Machine Learning (ML), and
other demanding computational tasks.Located in Sweden, this world-class
supercomputer will serve a diverse range of users across Europe,
including the scientific community, industry, and the public sector.
With robust security and data integrity standards, Arrhenius will be
ideally suited for sensitive research involving personal data, as well
as proprietary product development by private enterprises.The
procurement of Arrhenius adds a new mid-range supercomputer to the
EuroHPC JU portfolio of high-performance computing (HPC) systems,
further advancing the European Union’s mission to provide scientists and
industries across Europe with access to state-of-the-art supercomputing
infrastructure and services.Once operational, Arrhenius will be
complemented by MIMER, the EuroHPC AI Factory (AIF) located in Sweden,
which will include a new AI-optimised supercomputer to be deployed
through the recently closed tender procedure launched in May.The
installation of Arrhenius is scheduled to begin in September and is
planned to be completed early 2026.More details-HPE has been selected as
the vendor following a procurement process initiated in July 2024.The
system, named after Carl Axel Arrhenius, a Swedish geologist and chemist
who discovered gadolinite in 1787, will be hosted by Linköping
University, Sweden, where the National Academic Infrastructure for
Supercomputing in Sweden (NAISS) is located. Organisations such as RISE,
the Research Institute of Sweden and ENCCS, the EuroCC Competence
Centre Sweden, will be involved to ensure an appropriate uptake from
industrial and public sector users.The estimated total value for
Arrhenius is EUR 68.5 million. The machine will be co-funded by the
EuroHPC JU, with a budget stemming from the Digital Europe Programme
(DEP) and by contributions from the Swedish Research Council’s funding
for NAISS. The JU will co-fund up to 35% of the total cost of the
supercomputer. Access to computing resources on the new machine will be
jointly managed by the EuroHPC JU and NAISS in proportion to their
investments.NAISS official press release-Background-The EuroHPC JU is a
legal and funding entity that brings together the European Union and
participating countries to coordinate efforts and pool resources with
the objective of making Europe a world leader in supercomputing.To equip
Europe with a cutting-edge supercomputing infrastructure, the EuroHPC
JU has already procured 10 supercomputers, distributed across Europe.
Three of these EuroHPC supercomputers are now ranked among the world’s
top 10 most powerful supercomputers: Jupiter in Germany ranks at 4,
becoming Europe’s new fastest Supercomputer along with LUMI in Finland
(9th place), Leonardo in Italy (10th place).European scientists and
users from the public sector and industry can benefit from EuroHPC
supercomputers via the EuroHPC Access Calls no matter where in Europe
they are located, to advance science and support the development of a
wide range of applications with industrial, scientific and societal
relevance for Europe.Currently, the EuroHPC JU is also overseeing the
implementation of 13 AI factories across Europe that offer free,
customised support to SMEs and startups. One of these AIFs, MIMER, is
located in Sweden. MIMER will provide a mid-range AI-dedicated
supercomputer that prioritises cloud-style access mechanisms and
large-scale storage for sensitive data. The Swedish AI Factory will
particularly build AI support and training expertise in life sciences
and healthcare, material sciences, autonomous systems and the gaming
industry, all of which are areas of strength in Europe in general and
Sweden in particular. Additionally, the EuroHPC JU is deploying a
European Quantum Computing infrastructure, integrating diverse European
quantum computing technologies with existing supercomputers. The EuroHPC
JU also funds research and innovation projects to develop a full
European supercomputing supply chain, from processors and software to
applications to be run on these supercomputers and know-how to develop
strong European HPC expertise.Details-Publication date-10 July
2025-Author-European High-Performance Computing Joint Undertaking
Power Duos: Supercomputers and Quantum Computers.
Jülich
researchers are combining quantum computers with supercomputers. Such
hybrid systems are intended to unite the advantages of both worlds and
crack previously unsolvable scientific puzzles.Supercomputers and
quantum computers work completely differently. You could say that one is
a traditionalist, one a revolutionary. Supercomputers perform reliable
calculations according to the familiar rules of physics using ones and
zeros. Quantum computers, on the other hand, come from the bizarre world
of quantum physics: they use all numbers between one and zero, and are
capable of an unimaginable amount at the same time – but they are still
difficult to control.In future, these unequal computing masters will
work together as a power duo at Jülich. One such hybrid system is formed
by the established JURECA DC supercomputer and JADE, a 100-qubit
quantum simulator delivered by French company Pasqal, which has been in
operation at the Jülich Supercomputing Centre (JSC) since the end of
2024. Others are set to follow, including the new exascale supercomputer
JUPITER, which is currently being built at Jülich. JUPITER will be
coupled with the D-Wave Advantage2 system, an annealing quantum computer
recently acquired for the Jülich UNified Infrastructure for Quantum
computing (JUNIQ) (see infobox, page 30). This duo creates new
opportunities for breakthroughs in artificial intelligence and
optimization, for example in the field of logistics. Such hybrid systems
are also expected to find answers to some of the trickiest questions in
modern science, such as modelling complex climate scenarios or the
structures of giant molecules.We want to combine the advantages of both
systems. The supercomputer does most of the work and ensures a stable
workflow. The quantum computer steps in whenever its partner gets stuck
or takes too long to solve the problem.Kristel Michielsen, head of the
Jülich UNified Infrastructure for Quantum computing (JUNIQ). The
platform provides access to state-of-the-art quantum computers and the
possibility to connect supercomputers to quantum systems that are
already running.The best of both worlds“We want to combine the
advantages of both systems,” explains Prof. Kristel Michielsen from JSC.
“The supercomputer does most of the work and ensures a stable workflow.
The quantum computer steps in whenever its partner gets stuck or takes
too long to solve the problem.” One example would be climate
simulations: “The supercomputer performs the central modelling, while
the quantum computer takes on specific subtasks such as highly complex
optimization questions.” This could involve investigating atmospheric
chemistry, for example, where the multitude of chemical particles and
processes means that there is a huge number of possibilities to be
tested.As such modelling involves countless parameters, this would keep
even the most powerful supercomputers – such as the new exascale
computer JUPITER – busy for years or even decades. This is not the case
with quantum computers. Unlike conventional bits, their computing units,
qubits, can not only assume the values 0 and 1, but also any number of
values in between. A quantum processor therefore has the potential to
perform numerous operations in parallel, which is why it could calculate
significantly faster and more efficiently than a conventional computer.
“This saves time and energy,” says Michielsen.
a
JUPITER
The
JUPITER supercomputer will be the first exascale computer in Europe.
Coupling it with quantum computers is just one application. Its
computing power makes it one of the world’s most powerful supercomputers
for AI. This will allow AI applications to be developed, tested,
improved, and scaled faster than ever before. It is therefore only
logical that a central pillar of European AI infrastructure is also
being established in Jülich: the AI Factory. This will give small and
medium-sized enterprises, industry, and research institutions access to
JUPITER with tailored support for all AI applications. The JUPITER AI
Factory (JAIF) is being provided with around € 55 million in funding by
the European supercomputing initiative EuroHPC Joint Undertaking, the
German Federal Ministry of Research, Technology and Space, and the
ministries of science in North Rhine-Westphalia and Hesse. Several
leading German AI institutions have joined forces in this joint project.
a
JUNIQ
JUNIQ
– the Jülich UNified Infrastructure for Quantum computing – is part of
Forschungszentrum Jülich’s large future IT ecosystem. This unique
platform offers science and industry access to a wide range of quantum
systems at various stages of development – from state-of-the-art
commercial systems such as the D-Wave quantum annealer and quantum
simulators such as JADE to continuously optimized, experimental quantum
computers from projects such as QSolid and OpenSuperQPlus. Through
hybrid approaches, i.e. combining quantum computers with supercomputers,
and the integration of artificial intelligence, complex problems can be
addressed in completely new ways. Users also benefit from comprehensive
support in the development of algorithms and applications for quantum
computing.
JSC has already connected a small five-qubit system from
German–Finnish manufacturer IQM to its JURECA DC supercomputer and
carried out initial test experiments. A superconducting qubit system
developed by Jülich researchers in collaboration with Goethe University
Frankfurt and the companies ParTec and Quantum Machines will soon be
added, as well as an ion trap system from the German start-up eleQtron.
All three systems will be integrated into JSC’s supercomputing
infrastructure and are part of the JUNIQ user infrastructure, where FZJ
combines, develops, and tests a wide variety of quantum systems. “JUNIQ
offers users the unique opportunity to find the most suitable quantum
system for their needs and compare different concepts on a single
platform,” stresses Michielsen.
To allow the quantum computers to
fully leverage their strengths at the right moments, researchers first
need to coordinate the communication and methodology of the two
different types of computers. This requires software that takes into
account both traditional and quantum mechanical approaches. If all this
succeeds, the hybrid systems could answer important questions not only
in climate research, but also in chemistry, medicine, materials science,
finance, AI research, logistics, and quantum physics. Therefore, when
it comes to major scientific challenges, it could prove to be a great
advantage to have two systems cooperating that work in completely
different ways.Extensive expertise-Forschungszentrum Jülich’s broad
expertise in supercomputing and quantum computing really comes to the
fore with the development of such hybrid computers on the Jülich campus.
Back in 1987, the Jülich Supercomputing Centre (JSC) was the first
high-performance computing centre in Germany. Now, the first European
exascale computer, JUPITER, is being built there. “Exa” denotes a “1”
with 18 zeros, or a quintillion calculations per second. This is roughly
equivalent to the computing power of 1 million modern smartphones. The
Jülich supercomputer community also includes four other
supercomputers.Jülich’s quantum research is also unique in Germany. The
scientists cover the entire spectrum of quantum research – from quantum
theory, hardware construction, and software programming to the testing
and further development of finished components. Depending on the problem
at hand, the researchers work with very different systems, each with
their own characteristics – including a quantum annealer from the
Canadian company D-Wave. This makes it possible to try out different
techniques and power duos at Jülich.This text is taken from the 1/25
issue of effzett. Text: Janosch Deeg; Images: Forschungszentrum
Jülich/Sascha Kreklau
Augmented body surveillance: Human
microchip implantations and the omnipresent threat of function
creep-Author links open overlay panelMarie-Helen Maras a , Michelle D.
Miranda
https://doi.org/10.1016/j.techsoc.2023.102295
Highlights • Human microchip implants create augmented bodies that can be subject to surveillance.
• There are security, privacy, and data protection concerns associated with human microchip implantations.
• There is an observable function creep in human microchip implantation applications.
•
Barring any preventative laws, human microchip implantation data can be
accessed for criminal investigations and prosecutions.
• Potential users should be aware of and consider these risks prior to adopting such technologies.
Abstract
Implanted
microchips can store users' medical, financial, and other personal
information, and provide users with easy and quick access to various
locations and items. While adopted for their convenience outside of the
healthcare sector, these invasive, semi-permanent implantable devices
create augmented bodies that can be subject to ubiquitous surveillance.
Situating human microchip implantations within surveillance literature,
we draw from neoliberal perspectives of surveillance to examine
augmented bodies, particularly as sources for market activity and as
subjects of social control and sorting when these bodies are used as
access control mechanisms, payment methods, and tracking means in
employment, residential, commercial, and transportation sectors. History
has demonstrated time and time again how unfettered technology
applications and uses have led to real and/or perceived misuse by
private and public sectors. Through the lens of function creep, we
identify a pattern of expansion of applications and uses of technology
beyond those originally intended across new technologies, such as DNA
genetic genealogy databases, IoT wearables, and COVID-19 contact tracing
apps, and provide illustrative examples of function creep, particularly
the use of these technologies in criminal investigations and
prosecutions despite not being intended or marketed for such use. By
demonstrating the lack of clearly defined boundaries in the applications
and uses of various new technologies and their associated data, and the
ways they were misused, we demonstrate how human microchip
implantations are headed on a similar path. The current and potential
future uses of this technology raise concerns about the absence of
regulation, law, and policy barring or limiting its application and use
in specific sectors, and the impact of this technology on users’
security, data protection, and privacy. Undeniably, the present and
potential future functions, applications, uses, and extensions of human
microchip implantations in various sectors warrant a proactive
examination of their security, privacy, and data protection consequences
and the implementation of proactive policies to regulate new and
currently unregulated uses of this technology and its associated data
within these sectors.
Introduction
Human implanted technologies
have long been depicted in popular culture—in books, TV series, and
films. From biological implants serving to control bodily functions in
the 2018 film Upgrade, to child monitoring technologies in the 2017
episode of Arkangel in the Black Mirror television series [1], human
microchip implantations (HMIs) are viewed as science fiction or a
concern for future generations. However, is the transition of HMIs from
fiction to reality imminent? If they are currently in use, where are
they being used and why were they introduced? For those HMIs currently
in use, is regulation in place to prevent misuse or ensure that life
(reality) does not imitate art (science fiction)? These questions served
as a motivation for this study, which sought to: 1) situate HMIs in
surveillance literature; 2) identify the scope of HMI use and
applications; and 3) investigate the reasons and purposes for their
introduction, the justifications for their use, and the current and
future implications of their deployment and adoption.
Our work
situates function creep in the surveillance literature using it as an
analytical lens to examine HMIs. Like our predecessors who examined
function creep across other technologies, such as DNA databases [2], we
examine a particular technology – HMIs – and how this technology has
evolved over time. In developing our approach, we considered Kevin
Haggerty's assertion that “if there is ever public debate about a new
monitoring technology this tends to occur just prior to the tool being
incorporated into a concrete governmental initiative or expanded to new
populations” ([3], p. 165). And yet, we observed remarkable inattention
to HMIs before their deployment in several sectors and a lack of clearly
defined boundaries in both the uses and applications of this
technology, and the target population of the technology.
When
examining the evolution of HMIs, we draw attention to the way HMIs
expanded through extensions to various applications and target
populations. We highlight particularly concerning applications and uses
of HMIs, which use humans as access control, payment, and tracking
mechanisms in employment, residential, commercial, and transportation
sectors. With these applications and uses, HMIs can serve as a tool of
surveillance. Unlike other surveillance tools that exist in individuals’
environments (home or outside) or on their person (in the form of a
wearable device), this tool is embedded within human beings. These
microchips can be used to store and share personal, medical, financial,
and other information, track and surveil people, and grant access to a
particular device, room, building, facility, or establishment.
In
taking a critical lens to HMIs and the threat of function creep, we
consider the interface of reality and (science) fiction, both
ontologically and functionally. In the metaphysical space, we think
about how technology shapes our existence in a temporal context,
focusing on Heidegger's Dasein and the essence of technology—the
recognition and assignment of meaning with respect to new technology
(HMIs) helps to shape the human idea of existing within our everyday
world [4,5]. But, in thinking about human existence in which HMIs become
integrated, it becomes necessary to reconcile the emergence of the
cyborg (defined here broadly as the combination of the human physical
form with mechanical and/or electronic components). The dual
identity—human and machine—the cyborg of science fiction—presents
challenges to both individuality and Being. Considering the elusive
purpose of HMIs, the science fiction imagination presents such
technology as blurring the line between safety and danger—the decision
lies in whether HMIs will control the “other” (e.g., criminals) or if
they will be used to control “us” (e.g., the law-abiding citizen). From a
functional perspective, both social sorting and the pervasive reality
of surveillance capitalism means that behavior modification,
individualized cloning, and the hive mind can all contribute to the
surveillance and social control of bodies embedded with microchips
(augmented bodies or cyborgs) and the data they generate.
We engaged
in exploratory research to better understand the adoption of HMIs and
delineate issues and impacts associated with their adoption. This
approach was used to investigate the implications of HMI adoption. We
conducted a clearnet search to identify news reports and academic
journal articles covering HMIs, using various combinations of the terms
“microchip,” “embedded,” “implant” and “humans.” Searches were limited
to English language news reports and peer-reviewed journal articles
covering HMIs. Supplementary research was conducted on identified HMI
applications in private archival academic databases (e.g., Lexis Uni and
Elsevier's Science Direct). The searches led to the identification of
HMI use across various sectors, including food and agriculture,
environmental, healthcare, employment, residential, transportation, and
commercial sectors. Our search also revealed that microchip
implantations have been used for decades in certain sectors, presented
in part through the evolution of US Patents connected to current and
developing HMI technology. In our analysis, we identify possible future
uses of HMIs based on past experiences with other, more recent
technologies. We conclude by identifying gaps in existing regulation,
laws, policies, and practices in expanded HMI applications and uses,
looking particularly at security, privacy, and data protection
implications.
We present our exploratory approach in four major
parts. The first part provides an overview of microchip development and
applications, drawing attention to augmented bodies used for access
control, payment, and tracking. The second part provides an overview of
surveillance and the prevailing views of surveillance as a tool of
power, discipline, and/or control. In this section, we introduce the
potential of surveillance for consumer cloning, behavior modification,
and social sorting. The third part explores function creep as an element
of technology deployment. This concept of function creep is then linked
specifically to HMIs in the following part, drawing on the patterns
observed with the data derived from genetic genealogy databases (e.g.,
DNA ‘profiles’), public health apps (e.g., COVID-19 geolocations) and
Internet of Things (IoT) devices (e.g., health data derived from
wearable devices). This section also considers patterns of consumer
adoption of new technology, including HMIs. The last part considers the
threats and impacts of function creep on security, privacy, and data
protection by critically examining HMI capabilities, existing data
protection and HMI laws, and identifying gaps in technical and legal
controls.
Section snippets
Evolution of microchip applications
Innovations
within healthcare and public health, food and agriculture, and other
sectors that play critical roles in the protection of wildlife and
ecosystems have positively contributed to environmental, agricultural,
and health security. Microchips are implanted in wildlife and livestock
to monitor their health and movements and protect both animal and human
populations. The development of implanted devices gained traction in the
1960s, with the development of a US patent for tracking the
Surveilling augmented bodies
Conceptions
of surveillance, the targets of surveillance, the tools of
surveillance, and those conducting surveillance have shifted over time.
The word “panoptic” has been used to describe surveillance measures.
This term is derived from the prison design of Jeremy Bentham, which
consists of a circular prison with a central guard tower and prison
cells placed along the entire circumference of the structure [27]. The
central location of the guard tower enables the observation of each
prison cell
Function creep
Gary T. Marx recognized how new uses
for technology are identified and implemented over time [47]. Similarly,
Lyon argued that surveillance technologies are not limited to a single
purpose, but can be multifarious and eventually subject to change
[34,48,49]. These new uses and/or functions of technology result from
the push to integrate new technologies and systems into existing ones
for various reasons [50]. The next section introduces our theoretical
lens and framework for our analysis,
The security, privacy, and data protection lacuna
The
consequences of function creep have been explored across many
disciplines and technologies– DNA databases [2]; workplace surveillance
[113]; migration and crime control [60]; and public health [114], with
the latter extending to present day contract tracing apps implemented in
response to the COVID-19 pandemic [65]. A yet unexplored aspect of HMIs
are the consequences of the expansion of its functions and
applications. As the utilization of HMIs spreads and the resultant data
becomes
Conclusion
Because implantable devices enable the
extensive processing of subjects' personal data and the pervasive
surveillance of individuals, their locations, and associations, this
technology will contribute to the already extensive digital footprints
of individuals, resulting in more personal, medical, and financial
information reaching even more providers. This, in turn, increases the
number of providers that have access to users’ data, thereby increasing
the risk of personal data exposure. The lack
Credit author statement
Marie-Helen
Maras: project administration; conceptualization; investigation;
writing – original draft; writing – review and editing. Michelle D.
Miranda: conceptualization; investigation; writing – original draft;
writing – review and editing.
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Data Center Embedded Controllers
Establish System
Trust Chain With Our Platform Root of Trust Microcontrollers-The rapid
expansion of connected products has compelled developers of data center,
5G, communication, networking and industrial equipment to seek new ways
to keep their hardware, firmware and operating systems secure and
uncompromised. Security threats are increasing exponentially in
frequency, targeted devices, malignancy and costs of attacks. In today's
vast interconnected world, the need to provide greater security within a
product or system is becoming a standard requirement.
Quantum Computing Explained
Three
qubits appear in an artist’s conception as X-shaped icons that fit
together.A computer that could break the encryption that safeguards your
private information on the internet. A machine that can design powerful
new drugs by precisely simulating the behavior of individual molecules.
A device that optimizes complex supply chains to help companies get the
parts they need and assemble them in the most efficient way
possible.These are all examples of how an emerging technology — the
quantum computer — could change our world.These computers work by
harnessing quantum physics — the strange, often counterintuitive laws
that govern the universe at its smallest scales and coldest
temperatures. Today’s quantum computers are rudimentary and error-prone.
But if more advanced and robust versions can be made, they have the
potential to rapidly crunch through certain problems that would take
current computers years. That’s why governments, companies and research
labs around the world are working feverishly toward this goal.Quantum
computers will not replace our familiar “classical” computers. Rather,
the two types of machines could work together to solve problems that
stymie classical computers, potentially supercharging scientific
research in fields such as materials and drug discovery, giving a boost
to industry and upending cybersecurity as we know it.Let’s explore how
quantum computers work.What is quantum, anyway? Quantum physics
describes the universe at its smallest and most fundamental scales —
think atoms and molecules; light and energy. Things at these scales
behave very differently from everyday objects we’re familiar with.One of
the most important differences involves a concept called superposition.
Let’s start by considering an everyday, human-scale object such as a
person on a ladder. Depending on which rung the person stands on, they
have a certain amount of potential energy. (This potential energy
determines how fast the person would be moving when they hit the ground
if they were to jump off the ladder.) A person on the ground has the
smallest possible amount of energy in this system. Someone on the first
rung has slightly more energy, and so on up to the highest rung.By
contrast, tiny objects such as atoms can act as though they have two or
more distinct amounts of energy at once. In our ladder example, this
would be akin to simultaneously standing on the ladder’s lowest and
highest rungs — something that makes no sense for a person.Once placed
into this kind of mixed energy state, known as a “quantum
superposition,” an atom will remain there until it is measured or
disturbed by the outside world. Then the atom “collapses” to a single
energy state — following our analogy, to either the low or high rung of
the ladder.Superposition: A circle is split, with halves marked 0 and 1.
When a ruler appears, the entire circle becomes 1.A particle starts out
in a quantum superposition of energy state 0 and energy state 1. When
the particle is measured (represented by a ruler), it must
instantaneously and randomly “collapse” to be either fully in state 0 or
state 1.To cast this idea into familiar terms, the famous physicist
Erwin Schrödinger came up with a memorable, though absurd, thought
experiment: Imagine a perfectly sealed box containing a cat and a poison
trap that can be triggered by the decay of a radioactive atom. Because
the decay of the atom is uncertain, at any given time, the cat is in a
superposition of dead and alive. Only when someone opens the box and
measures the cat does its state “collapse” to being either definitively
alive or definitively dead. Real cats can’t be both alive and dead, of
course, but Schrödinger’s imaginary cat has become an enduring metaphor
to help people grapple with the strangeness of superposition.Building on
the superposition concept, multiple atoms or other quantum objects can
be entangled with each other to share a single quantum state. Now
imagine several cats in Schrödinger’s box, potential victims of the same
trap. These cats are “entangled” in a superposition of all being alive
or all being dead. When someone opens the box, not just the state of one
cat but those of all the cats immediately collapse, and each cat is
found to be fully alive or fully dead. “Entanglement means you’ve got at
least two things that are always connected; they have no independent
existence,” explains NIST physicist Andrew Wilson.Entanglement: Two
circles connected with a wavy line are each split, with halves marked 0
and 1. When a ruler appears, one circle becomes entirely 0 and the other
is entirely 1.A pair of particles start out each in a quantum
superposition of energy state 0 and energy state 1. Because the
particles are also entangled with each other, when one is measured
(represented by a ruler), both must randomly “collapse” such that one is
fully in state 0 and the other is fully in state 1. The collapse is
instantaneous for both particles, no matter how far apart they are.These
scenarios strike us as absurd when applied to familiar objects such as
cats. But at the atomic level, this is how the world works. Tiny objects
such as atoms can exist in multiple states simultaneously. And these
states can be entangled with those of other objects even when the
objects are far apart. “Let’s say you have an entangled pair of
particles and you put one on the Moon and the other on the surface of
the Earth. If you then do something to the one on the Earth, you
simultaneously affect the other,” Wilson says. “It’s kind of
romantic!”We’ll soon explore how physicists use these ideas to build
quantum computers. But first we need to understand ...What is a
computer? These days, we use computers for just about everything: gaming
and streaming, banking and shopping, following our favorite sports
teams and chatting with friends and family members. But we rarely think
about what a computer is or how it works.At its most fundamental level, a
computer is any device that takes in data, processes it, stores it and
spits it out. The phones in our pockets, the servers in data centers,
the microprocessors in our cars and the room-sized supercomputers at
national labs: All of these digital computers encode and process
information using “bits.” Bits are “binary digits” that encode
information — text, graphics and so on — as 1s and 0s. For example,
computers typically represent the letter “A” using the bit string
“01000001.”But bits, like the computers they are part of, are not just
mathematical concepts. They need to be realized in physical objects such
as tiny bar magnets or electric switches that can be placed into one of
two distinct states, say pointed up or pointed down.Bits are very good
at what they do. Put a bit into a “0” or “1” state and it will usually
stay there for a long time, meaning the information it encodes is stable
and long-lasting. But bits are also limited.Quantum computers also have
input, output, information processing and memory. But instead of
regular classical bits, quantum computers use quantum bits, or qubits.
Like Schrödinger’s unfortunate cat, qubits can be put into
superpositions of multiple states. In other words, a qubit can be in
state 0, state 1, or a mix of the two. And the quantum states of
individual qubits can be entangled with each other.These capabilities
give quantum computers their superpower. Whereas two classical bits
contain just two pieces of information (0 and 1, for example, or 1 and
0), two qubits can contain a superposition of four combinations of 0s
and 1s simultaneously. Three qubits can contain eight combinations; four
qubits, 16 combinations and so on. Each additional qubit doubles the
number of combinations: an exponential increase.Someone using a quantum
computer must first entangle qubits to harness their exponential
computing power. The operator then carries out operations on the qubits,
such as addition, multiplication or more complicated computations.
Depending on the type of quantum computer, electromagnetic signals or
lasers create the entanglement and operations.Though they are capable of
exponential computation, quantum computers are limited in the amount of
data they can extract from these computations — a fact that’s often
lost in popular descriptions giving the impression that quantum
computers try every solution to a problem at once.“Different
computations can indeed be done in superposition, achieving a kind of
parallel computing,” says Stephen Jordan, a Google quantum computing
researcher who was a longtime NIST staff member and Joint Center for
Quantum Information and Computer Science fellow-But contrary to popular
belief, this doesn’t allow quantum computers to do an efficient ‘brute
force’ search over all the potential solutions.“The measurement at the
end of the computation can only extract a small amount of information
about the results of all of these computations,” Jordan explains. “The
key is to design the measurement so that it extracts useful information
about the whole set of results done in superposition.”(Note: This
article describes quantum computers that do computations using logic
gates, similar to classical computers. Some scientists and companies are
pursuing another technology known as “quantum annealing” that could be
used to solve certain physics and optimization problems faster than
classical computers can.) What could quantum computers do? At a 1981
gathering of physicists outside Boston, the famous physicist Richard
Feynman spoke about the possibility of “simulating physics with
computers.” Though other scientists had independently developed similar
ideas around the same time, Feynman’s talk is often credited with
launching the field of quantum computing.Since then, scientists have
explored how quantum computers could, in theory, simulate the
fundamental quantum rules that govern molecules, chemicals and materials
— something today’s computers can only approximate with great effort.
If quantum computers eventually become large and powerful enough,
scientists hope that such quantum simulations could bring about major
advances in materials science, drug development and other areas.
Potentially transformative “killer apps” for quantum simulation could
involve discovering a new blockbuster drug or chemical catalysts that
make the production of fertilizer or the capture of greenhouse gases
from the air more efficient.In 1994, a mathematician named Peter Shor
published a paper-about a very different application that instantly made
quantum computing a national security issue. The algorithms that
encrypt much of our data work by multiplying very large prime numbers
together to create a secret key — something that’s very hard for
classical computers to undo. Shor’s paper described a quantum algorithm
that could quickly factor the immense numbers that are products of these
huge prime numbers, potentially putting much of the world’s encrypted
information at risk.Scientists also believe quantum computers could
outpace classical computers at solving complicated optimization problems
such as helping companies organize complex processes such as airplane
assembly in more efficient ways.Most of these applications are years —
perhaps even decades — in the future. But scientists have started to
publish papers claiming that quantum computers have demonstrated a
“quantum advantage,” meaning they can outdo classical computers for
certain tasks. Quantum computers have been used to calculate the
energies of small molecules, for example, and simulate the magnetic
properties of collections of interacting atoms.So far, none of these
early demonstrations have proved truly useful, says Scott Glancy, a
physicist at NIST. And in some cases, scientists later showed that
traditional computers could equal or exceed the performance of quantum
processors for some tasks. The demonstrations do, however, prove that
quantum computers work and can be scaled up.“It seems to me we’re just
on the threshold of quantum systems doing genuinely new simulations that
we can’t do classically,” says Glancy.Beyond these practical
applications, quantum computers could offer a new way to probe the
fundamental nature of reality. A full-scale quantum computer, if
successfully built, would contain some of the most complex quantum
states ever created (assuming aliens have not already built such
devices). Those states would provide an important, albeit not
surprising, confirmation of quantum theory. If, on the other hand,
scientists find that a large-scale quantum computer cannot be built,
that would be “shocking,” says Glancy. “It might inspire a revolution in
physics. In my opinion that is a good reason to build a quantum
computer.”Why don’t we have quantum computers today? Qubits are
exquisite but fragile. A stray electric or magnetic field, temperature
fluctuations or even a cosmic ray can ruin a superposition or
entanglement. This forces qubits into a 0 or 1 state in which they act
like ordinary bits. Anyone building a quantum computer must find ways to
manipulate the qubits carefully while protecting them from outside
disturbances.Moreover, a single qubit by itself is worth little. For a
quantum device to do something useful, many qubits must be entangled
with each other while sustaining superpositions. The best quantum
computers today contain hundreds of interconnected qubits and make an
error roughly once in every thousand operations. An error changes the
state of a qubit, destroying or corrupting the information it
carries.(By contrast, a classical computer makes around one error, such
as a bit randomly flipping from 0 to 1, for every quintillion — 1
followed up 18 zeroes — calculations. And correcting errors in a
classical computer is much easier.) Industry, university and government
researchers around the world are racing to make more reliable qubits and
build electronics and laser systems that create entanglement more
efficiently and robustly. And they are experimenting with many kinds of
qubits. In theory, any particle or system that obeys the rules of
quantum physics, from atoms to tiny circuits to semiconductors, can act
as a qubit.Each qubit has advantages and disadvantages. For example, one
of the most popular qubit types uses electrically charged atoms known
as ions. The quantum energy states of electrons inside these ions
represent the 0s and 1s (and combinations thereof) for quantum
computation. Ion qubits can sustain quantum superpositions for a long
time, but they are relatively sluggish at performing computations.Square
device surrounded by a design of gold wiring.A gold-on-alumina ion trap
inside a case that protects ions from electrical interference.Another
popular qubit uses tiny circuits made from superconductors — materials
that conduct electricity without resistance at very cold temperatures.
The behavior of the electrons in the circuits creates quantized energy
states that can be used to encode 0s and 1s. These qubits allow for fast
computations and can be made using existing chip manufacturing
techniques. But their quantum states are more fragile and shorter-lived
than those of ion qubits.Colorized micrograph of superconducting
circuit-A chip combining a superconducting qubit (pink) for storing
quantum information, a quantum bus (green) for transporting information,
and a switch (purple) that tunes interactions between the other two
components.Scientists are also experimenting with qubits based on arrays
of neutral (non-electrically charged) atoms, atoms embedded in
diamonds, particles of light known as photons-and small bits of
silicon.Some researchers are also trying to develop a radically
different type of qubit, known as a “topological” qubit, that would have
some built-in immunity to errors. In theory, topological qubits could
encode quantum information into the braiding pattern of “quasiparticles”
that emerge from the collective behavior of individual particles such
as electrons. These braiding patterns, and thus the quantum states,
would be protected from some of the outside disturbances that can
disrupt other qubits. Topological qubits require temperatures near
absolute zero and complicated structures often involving superconducting
and semiconducting materials. They have proved challenging to build,
and researchers are still seeking definitive evidence that they have
managed to make one. Ultimately, quantum computers may marry multiple
kinds of qubits so that each can play to its strengths. Superconducting
or photonic qubits could crunch through operations quickly, for example,
then transfer their information to ion or diamond qubits for storage.
What
is NIST on a Chip? -NIST has embarked on a revolutionary program that
will bring cutting-edge measurement-science technology and expertise
from our labs directly to users in commerce, medicine, defense and
academia. We are developing a suite of inherently accurate measurement
technologies that operate according to the precise, time-tested
principles of quantum physics.The ultimate goal of NIST on a Chip
technology is for it to be deployed nearly anywhere and anytime, without
the need for NIST’s traditional measurement services. We are seeking
partnerships with the U.S. private sector and other government agencies
to bring these technologies to commercial reality and unleash new
capabilities for American innovation. Learn more about the promise of
NIST on a Chip.
Introduction-The National Institute of Standards
and Technology (NIST) has launched NIST on a Chip, a program that will
bring cutting-edge measurement-science technology and expertise from our
labs directly to users in industry, defense, medicine and academia.
NIST on a Chip (NOAC) aims to make ultra-reliable measurement technology
available nearly anywhere and anytime. We are seeking partnerships with
the U.S. private sector to bring these technologies to commercial
reality and unleash new capabilities for American innovation.A
microfluidic lab on a chip device sitting on a polystyrene dish.An early
experimental microfluidic lab-on-a-chip device sitting on a polystyrene
dish. Stainless steel needles inserted into the device serve as access
points for fluids into small channels within the device, which are about
the size of a human hair.NOAC technology will bring world-leading,
NIST-level accuracy to factory floors, hospital diagnostic centers,
commercial and military aircraft, research labs and ultimately homes,
vehicles and personal devices.The program is creating prototypes for a
new generation of ultra-compact, inexpensive, low-power measurement
tools for time and frequency, distance, mass and force, temperature and
pressure, electrical and magnetic fields, current and voltage, fluid
volume and flow, and more. Because these devices are directly based on
the rules of quantum physics, they are inherently accurate and reliable.
These NIST-pioneered technologies will be manufactured and distributed
by the private sector, opening new tech-transfer and lab-to-market
opportunities in accordance with NIST’s goal of strengthening U.S.
economic competitiveness by supporting advanced manufacturing.Breaking
the Calibration Cycle.It’s not enough to have the latest and greatest
equipment for accurately measuring the size of a new aircraft wing or
administering the precise dose of a lifesaving new drug. Such
measurement equipment must regularly be calibrated against a reliable
reference or standard to make sure it’s producing accurate results. At
present, many calibrations entail considerable downtime as users
periodically send valuable devices or in-house standards to NIST or
other calibration facilities for testing against U.S. national
standards, and then wait for the instruments to be shipped
back.Infographic shows steps from instrument in lab being sent to NIST
for calibration and returning to the lab.NIST on a Chip, by contrast,
aims to make possible universal, in-house access to mass-produced,
robust, miniaturized instruments and standards that can be traced to
U.S. national standards and the International System of Units (SI).
These instruments will not require external calibration because their
operation relies on fundamental constants and unchanging quantum
phenomena.Low Production CostsMost NOAC devices are intended to be
manufacturable with the same kind of silicon-based technology and
fabrication processes already used to make integrated circuits and
microelectromechanical systems (MEMS). That should result in devices
that are both inexpensive and rugged, with dimensions that are easily
incorporated into new or existing equipment.At present, the evolving
program is planned to include robust projects across the NIST
laboratories in multiple technology areas. Click on each link for
detailed information; we will be adding more links soon.
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