Ipg Photonics Corp (IPGP) |
|
|
|
Ipg Photonics's Customers Performance
IPGP
|
IPGP's Source of Revenues |
Ipg Photonics's Corporate Customers have recorded an advance in their cost of revenue by 4.15 % in the 4 quarter 2023 year on year, sequentially costs of revenue grew by 28.88 %. During the corresponding time, Ipg Photonics Corp revenue deteriorated by -10.46 % year on year, sequentially revenue fell by -0.75 %. While revenue at the Ipg Photonics Corp's corporate clients recorded rose by 3.21 % year on year, sequentially revenue grew by 29.9 %.
• List of IPGP Customers
|
|
Ipg Photonics's Customers have recorded an advance in their cost of revenue by 4.15 % in the 4 quarter 2023 year on year, sequentially costs of revenue grew by 28.88 %, for the same period Ipg Photonics Corp revnue deteriorated by -10.46 % year on year, sequentially revnue fell by -0.75 %.
• List of IPGP Customers
Select the Relationship:
|
|
Select the Category:
|
|
Customers Net Income fell in Q4 by |
Customers Net margin fell to % |
-4.91 % |
13.4 % |
Ipg Photonics's Comment on Sales, Marketing and Customers
Materials Processing
The most significant materials processing applications for fiber lasers are
cutting, welding and brazing, marking and engraving, additive manufacturing
such as 3D printing and ablation. Other applications include micro-processing,
surface treatment, drilling, and annealing.
Cutting and Welding Applications. Laser-based cutting technology has several
advantages compared to alternative technologies. Laser cutting is fast, flexible
and highly precise and can be used to cut complex contours on flat, tubular
or three-dimensional materials. The laser source can be programmed to process
many different kinds of materials such as steel, aluminum, brass, copper, glass,
ceramic and plastic at various thicknesses. Laser cutting technology is a non-contact
process that is easy to integrate into an automated production line and is not
subject to wear of the cutting medium. We sell low, mid and high power ytterbium
fiber lasers for laser cutting. High electrical efficiency, low maintenance
and operating cost, high beam quality, wide operating power range, power stability
and small spot size are some of the qualities offered by IPG fiber lasers for
many cutting applications, which enable customers to cut a variety of materials
faster.
Laser welding offers several important advantages compared to conventional welding
technology as it is non-contact, easy to automate, provides high process speed
and results in narrow-seamed, high-quality welds that generally require little
or no post-processing machining. The high beam quality of our fiber lasers coupled
with high CW power offer deep penetration welding as well as shallow conduction
mode welding. In addition, fiber lasers can be focused to a small spot with
extremely long focal lengths, enabling remote welding "on the fly,"
a flexible method of three-dimensional welding in which the laser beam is positioned
by a robot-guided scanner. Such remote welding stations equipped with fiber
lasers are used for welding door panels and seat backs, the multiple welding
of spot and lap welds over the entire auto body frame, tailor blank welding
and welding "body-in-white," which is welding pieces of metal with
different thicknesses for automotive applications. Typically, mid to high power
ytterbium fiber lasers and long-pulse QCW ytterbium fiber lasers are used in
welding applications. Our products are used also for laser brazing of visible
joints in automobiles such as tailgates, roof joints and columns. Brazing is
a method of joining sheet metal by using a melted filler material similar to
soldering but requiring higher temperatures.
3D Printing. Historically, metalworking has been performed with processes that
remove material to produce component parts. The development of 3D printing technology
enables the production of three-dimensional objects from digital design data
through an additive manufacturing process, which builds up components in layers
using materials that are available in fine powder form. 3D printers take advantage
of improvements in computing power and motion and process control to deposit
a range of materials, including metals, plastics and composite materials, accurately
at high speed. Within metal-based 3D printing processes that include laser metal
deposition (LMD) and selective laser melting (SLM), a laser beam is used to
fuse metallic powder at points defined by computer-generated design data. In
many metal-based 3D printers, multiple laser sources are used to to fuse the
metallic powder more quickly and at multiple angles. 3D printing permits highly
complex structures, with a high degree of customization capability and significantly
less waste than subtractive manufacturing processes. The trends toward automation
and miniaturization, as well as the stability and reliability of our fiber lasers
have played important roles in the development of additive manufacturing technology.
Marking and Engraving. With the increasing need for source traceability, component
identification and product tracking as a means of reducing product liability
and preventing falsification, as well as the demand for modern robotic production
systems, manufacturers increasingly demand marking systems capable of applying
serialized alphanumeric, graphic or bar code identifications directly onto their
manufactured components. Laser engraving is similar to marking but forms deeper
grooves in the material. In contrast to conventional acid etching and ink-based
technologies, lasers can mark a wide variety of metal and non-metal materials,
such as ceramic, glass and plastic surfaces, at high speeds and without contact
by changing the surface structure of the material or by engraving. Laser marking
systems can be easily integrated into a customers production process and do
not subject the item being marked to mechanical stress. Our ytterbium pulsed
fiber lasers are used for these applications.
In the semiconductor industry, lasers typically are used to mark wafers and
integrated circuits. In the electronics industry, lasers typically are used
to mark electrical components such as contactors, relays and printed circuit
boards. Consumer electronic devices such as mobile phones, computers and handheld
computers contain many parts that are laser-marked, including keyboards, logos
and labels. With the increase in marking speed in the past few years, the cost
of laser marking has decreased. In the photovoltaic or solar panel industry,
pulsed lasers increasingly are used to remove materials and to scribe, or cut,
solar cells. The high beam quality, increased peak output powers, flexible fiber
delivery and competitive price of fiber lasers have accelerated the adoption
of fiber lasers in these low power applications.
Micro-Processing and Fine Processing. The trend toward miniaturization in numerous
industries such as consumer electronics, as well as innovations in materials
and structures, is driving end users to utilize lasers in processing and fabrication.
The ability of lasers to cut, weld, drill, ablate, etch and add materials on
a fine scale is enabling new technologies and products across many industries.
Our low power CW and QCW lasers are used to cut medical stents and weld medical
batteries. In photovoltaic manufacturing, our lasers etch and perform edge isolation
processes. The aerospace industry requires precise manufacturing of engine parts
so that cooling is effective and aerospace manufacturers use lasers to conduct
percussion drilling. Processing of plastics and semi-conductors require short
pulse and high energy lasers, in the green, UV and mid-IR wavelengths.
Advanced Applications
Our fiber lasers and amplifiers are utilized by commercial firms and by academic
and government institutions worldwide for manufacturing of commercial systems
and for research in advanced technologies and products. These markets may use
specialty products developed by us or commercial versions of our products.
Special Projects. Due to the high power, compactness, performance, ruggedness
and electrical efficiency of our fiber lasers and amplifiers, we sell our commercial
products for government research and projects. These include materials testing,
ordnance destruction, coherent beam combining, directed energy demonstrations,
advanced communications and research.
Research and Development. Our products are used in a variety of applications
for research and development by scientists and industrial researchers, including
atom trapping. In addition, our lasers and amplifiers are used to design, test
and characterize components and systems in a variety of markets and applications.
Optical Pumping and Harmonic Generation. Several types of our lasers are used
to optically pump other solid-state lasers and for harmonic generation and parametric
converters to support research in sensing, medical and other scientific research
in the IR and visible wavelength domains. Our lasers are used as a power source
for these other lasers. Green visible lasers are used to pump titanium sapphire
lasers. Visible lasers can be used in cinema projection, amusement parks, planetariums
and light shows.
Remote Sensing. Our products are used in light detection and ranging ("LIDAR"),
a laser technique for remote sensing. Optical fiber can be used as a sensor
for measuring changes in temperature, pressure and gas concentration in oil
wells, atmospheric and pollution measurements and seismic exploration.
Obstacle Warning and Mapping. Our products are used for obstacle warning and
3-dimensional mapping of earth surfaces.
Communications
We design and manufacture enhanced optical transmission modules and systems
and DWDM transport systems for transmission of multiple wavelength channels
over a single optical fiber.
We make optical pluggable systems, based upon mixed signal ASIC proprietary
designs, intended to simplify optical networks and reduce customer capital costs.
These are integrated into advanced 100G/400G software-defined, flexible and
configurable coherent DWDM transceiver modules to comprise a "system-in-module".
Major customers of this technology include a leading MSO, a large US data center
operator and leading optical network system integrators.
IPGs fiber amplifiers are deployed in some of the worlds largest broadband
FTTH networks. In addition, we design and manufacture transceivers for interconnecting
electronic equipment within telecommunications, cable MSO, and data center networks.
DWDM. DWDM is a technology that expands the capacity of optical networks, allowing
service providers to extend the life of existing fiber networks and reduce operating
and capital costs by maximizing bandwidth capacity. We provide a broad range
of high power products for DWDM applications including EDFAs and Raman lasers.
We provide a DWDM transport system that offers service providers and private
network operators a simple, flexible, optical layer solution scalable to 80
channels that aggregates and multiplexes multiprotocol clients into optical
transport network signals operating at 10, 40 and 100 gigabits per second per
channel. We also provide both fixed wavelength DWDM transceivers and tunable
DWDM transceivers that are capable of dynamically tuning across a range of wavelengths.
Broadband Access. The delivery to subscribers of television programming and
Internet-based information and communication services is converging, driven
by advances in Internet Protocol ("IP") technology and by changes
in the regulatory and competitive environment. Fiber optic lines now offer connection
speeds of up to 10 gigabits per second to the subscriber, or 1,000 times faster
than digital subscriber lines ("DSL"), or cable links. We offer a
series of specialty multi-port EDFAs and cable television ("TV") nodes
and transmitters that support different types of passive optical network architectures,
enabling high-speed data, voice, video on demand and high-definition TV. We
provide an EDFA that supports up to 64 output ports, which allows service providers
to support a high number of customers in a small space, reducing overall power
consumption and network cost. End users for our products include communications
network operators for video wavelength division multiplexing overlay solutions,
operators of metro and long-haul networks for DWDM and amplification solutions,
as well as cable and multiple system operators for optical amplification solutions.
Medical
We sell our commercial fiber and diode lasers to OEMs that incorporate our products
into their medical laser systems. Our ultrafast and CW ytterbium, erbium and
thulium fiber lasers from 1 to 150 watts and diode laser systems can be used
in various medical and biomedical applications. Aesthetic applications addressed
by lasers include skin rejuvenation, hair removal, and treatment of pigmented
and vascular lesions. Purchasers use our diode lasers in dental and skin rejuvenation
procedures. Through our medical business, we are developing laser systems for
dental (soft tissue and bone surgery) and surgical (benign prostatic hyperplasia
and lithotripsy) aesthetic, and veterinary uses. Other medical procedures are
also being investigated.
We sell our products globally to OEMs, system integrators and end users in
a wide range of diverse markets who have the in-house engineering capability
to integrate our products into their own systems. We have thousands of customers
worldwide. Our primary end market is materials processing, comprised of general
manufacturing, automotive, heavy industry, aerospace, consumer products, medical
device manufacturing, natural resources, photovoltaic, semiconductor and electronics.
|
Ipg Photonics's Comment on Sales, Marketing and Customers
Materials Processing
The most significant materials processing applications for fiber lasers are
cutting, welding and brazing, marking and engraving, additive manufacturing
such as 3D printing and ablation. Other applications include micro-processing,
surface treatment, drilling, and annealing.
Cutting and Welding Applications. Laser-based cutting technology has several
advantages compared to alternative technologies. Laser cutting is fast, flexible
and highly precise and can be used to cut complex contours on flat, tubular
or three-dimensional materials. The laser source can be programmed to process
many different kinds of materials such as steel, aluminum, brass, copper, glass,
ceramic and plastic at various thicknesses. Laser cutting technology is a non-contact
process that is easy to integrate into an automated production line and is not
subject to wear of the cutting medium. We sell low, mid and high power ytterbium
fiber lasers for laser cutting. High electrical efficiency, low maintenance
and operating cost, high beam quality, wide operating power range, power stability
and small spot size are some of the qualities offered by IPG fiber lasers for
many cutting applications, which enable customers to cut a variety of materials
faster.
Laser welding offers several important advantages compared to conventional welding
technology as it is non-contact, easy to automate, provides high process speed
and results in narrow-seamed, high-quality welds that generally require little
or no post-processing machining. The high beam quality of our fiber lasers coupled
with high CW power offer deep penetration welding as well as shallow conduction
mode welding. In addition, fiber lasers can be focused to a small spot with
extremely long focal lengths, enabling remote welding "on the fly,"
a flexible method of three-dimensional welding in which the laser beam is positioned
by a robot-guided scanner. Such remote welding stations equipped with fiber
lasers are used for welding door panels and seat backs, the multiple welding
of spot and lap welds over the entire auto body frame, tailor blank welding
and welding "body-in-white," which is welding pieces of metal with
different thicknesses for automotive applications. Typically, mid to high power
ytterbium fiber lasers and long-pulse QCW ytterbium fiber lasers are used in
welding applications. Our products are used also for laser brazing of visible
joints in automobiles such as tailgates, roof joints and columns. Brazing is
a method of joining sheet metal by using a melted filler material similar to
soldering but requiring higher temperatures.
3D Printing. Historically, metalworking has been performed with processes that
remove material to produce component parts. The development of 3D printing technology
enables the production of three-dimensional objects from digital design data
through an additive manufacturing process, which builds up components in layers
using materials that are available in fine powder form. 3D printers take advantage
of improvements in computing power and motion and process control to deposit
a range of materials, including metals, plastics and composite materials, accurately
at high speed. Within metal-based 3D printing processes that include laser metal
deposition (LMD) and selective laser melting (SLM), a laser beam is used to
fuse metallic powder at points defined by computer-generated design data. In
many metal-based 3D printers, multiple laser sources are used to to fuse the
metallic powder more quickly and at multiple angles. 3D printing permits highly
complex structures, with a high degree of customization capability and significantly
less waste than subtractive manufacturing processes. The trends toward automation
and miniaturization, as well as the stability and reliability of our fiber lasers
have played important roles in the development of additive manufacturing technology.
Marking and Engraving. With the increasing need for source traceability, component
identification and product tracking as a means of reducing product liability
and preventing falsification, as well as the demand for modern robotic production
systems, manufacturers increasingly demand marking systems capable of applying
serialized alphanumeric, graphic or bar code identifications directly onto their
manufactured components. Laser engraving is similar to marking but forms deeper
grooves in the material. In contrast to conventional acid etching and ink-based
technologies, lasers can mark a wide variety of metal and non-metal materials,
such as ceramic, glass and plastic surfaces, at high speeds and without contact
by changing the surface structure of the material or by engraving. Laser marking
systems can be easily integrated into a customers production process and do
not subject the item being marked to mechanical stress. Our ytterbium pulsed
fiber lasers are used for these applications.
In the semiconductor industry, lasers typically are used to mark wafers and
integrated circuits. In the electronics industry, lasers typically are used
to mark electrical components such as contactors, relays and printed circuit
boards. Consumer electronic devices such as mobile phones, computers and handheld
computers contain many parts that are laser-marked, including keyboards, logos
and labels. With the increase in marking speed in the past few years, the cost
of laser marking has decreased. In the photovoltaic or solar panel industry,
pulsed lasers increasingly are used to remove materials and to scribe, or cut,
solar cells. The high beam quality, increased peak output powers, flexible fiber
delivery and competitive price of fiber lasers have accelerated the adoption
of fiber lasers in these low power applications.
Micro-Processing and Fine Processing. The trend toward miniaturization in numerous
industries such as consumer electronics, as well as innovations in materials
and structures, is driving end users to utilize lasers in processing and fabrication.
The ability of lasers to cut, weld, drill, ablate, etch and add materials on
a fine scale is enabling new technologies and products across many industries.
Our low power CW and QCW lasers are used to cut medical stents and weld medical
batteries. In photovoltaic manufacturing, our lasers etch and perform edge isolation
processes. The aerospace industry requires precise manufacturing of engine parts
so that cooling is effective and aerospace manufacturers use lasers to conduct
percussion drilling. Processing of plastics and semi-conductors require short
pulse and high energy lasers, in the green, UV and mid-IR wavelengths.
Advanced Applications
Our fiber lasers and amplifiers are utilized by commercial firms and by academic
and government institutions worldwide for manufacturing of commercial systems
and for research in advanced technologies and products. These markets may use
specialty products developed by us or commercial versions of our products.
Special Projects. Due to the high power, compactness, performance, ruggedness
and electrical efficiency of our fiber lasers and amplifiers, we sell our commercial
products for government research and projects. These include materials testing,
ordnance destruction, coherent beam combining, directed energy demonstrations,
advanced communications and research.
Research and Development. Our products are used in a variety of applications
for research and development by scientists and industrial researchers, including
atom trapping. In addition, our lasers and amplifiers are used to design, test
and characterize components and systems in a variety of markets and applications.
Optical Pumping and Harmonic Generation. Several types of our lasers are used
to optically pump other solid-state lasers and for harmonic generation and parametric
converters to support research in sensing, medical and other scientific research
in the IR and visible wavelength domains. Our lasers are used as a power source
for these other lasers. Green visible lasers are used to pump titanium sapphire
lasers. Visible lasers can be used in cinema projection, amusement parks, planetariums
and light shows.
Remote Sensing. Our products are used in light detection and ranging ("LIDAR"),
a laser technique for remote sensing. Optical fiber can be used as a sensor
for measuring changes in temperature, pressure and gas concentration in oil
wells, atmospheric and pollution measurements and seismic exploration.
Obstacle Warning and Mapping. Our products are used for obstacle warning and
3-dimensional mapping of earth surfaces.
Communications
We design and manufacture enhanced optical transmission modules and systems
and DWDM transport systems for transmission of multiple wavelength channels
over a single optical fiber.
We make optical pluggable systems, based upon mixed signal ASIC proprietary
designs, intended to simplify optical networks and reduce customer capital costs.
These are integrated into advanced 100G/400G software-defined, flexible and
configurable coherent DWDM transceiver modules to comprise a "system-in-module".
Major customers of this technology include a leading MSO, a large US data center
operator and leading optical network system integrators.
IPGs fiber amplifiers are deployed in some of the worlds largest broadband
FTTH networks. In addition, we design and manufacture transceivers for interconnecting
electronic equipment within telecommunications, cable MSO, and data center networks.
DWDM. DWDM is a technology that expands the capacity of optical networks, allowing
service providers to extend the life of existing fiber networks and reduce operating
and capital costs by maximizing bandwidth capacity. We provide a broad range
of high power products for DWDM applications including EDFAs and Raman lasers.
We provide a DWDM transport system that offers service providers and private
network operators a simple, flexible, optical layer solution scalable to 80
channels that aggregates and multiplexes multiprotocol clients into optical
transport network signals operating at 10, 40 and 100 gigabits per second per
channel. We also provide both fixed wavelength DWDM transceivers and tunable
DWDM transceivers that are capable of dynamically tuning across a range of wavelengths.
Broadband Access. The delivery to subscribers of television programming and
Internet-based information and communication services is converging, driven
by advances in Internet Protocol ("IP") technology and by changes
in the regulatory and competitive environment. Fiber optic lines now offer connection
speeds of up to 10 gigabits per second to the subscriber, or 1,000 times faster
than digital subscriber lines ("DSL"), or cable links. We offer a
series of specialty multi-port EDFAs and cable television ("TV") nodes
and transmitters that support different types of passive optical network architectures,
enabling high-speed data, voice, video on demand and high-definition TV. We
provide an EDFA that supports up to 64 output ports, which allows service providers
to support a high number of customers in a small space, reducing overall power
consumption and network cost. End users for our products include communications
network operators for video wavelength division multiplexing overlay solutions,
operators of metro and long-haul networks for DWDM and amplification solutions,
as well as cable and multiple system operators for optical amplification solutions.
Medical
We sell our commercial fiber and diode lasers to OEMs that incorporate our products
into their medical laser systems. Our ultrafast and CW ytterbium, erbium and
thulium fiber lasers from 1 to 150 watts and diode laser systems can be used
in various medical and biomedical applications. Aesthetic applications addressed
by lasers include skin rejuvenation, hair removal, and treatment of pigmented
and vascular lesions. Purchasers use our diode lasers in dental and skin rejuvenation
procedures. Through our medical business, we are developing laser systems for
dental (soft tissue and bone surgery) and surgical (benign prostatic hyperplasia
and lithotripsy) aesthetic, and veterinary uses. Other medical procedures are
also being investigated.
We sell our products globally to OEMs, system integrators and end users in
a wide range of diverse markets who have the in-house engineering capability
to integrate our products into their own systems. We have thousands of customers
worldwide. Our primary end market is materials processing, comprised of general
manufacturing, automotive, heavy industry, aerospace, consumer products, medical
device manufacturing, natural resources, photovoltaic, semiconductor and electronics.
IPGP's vs. Customers, Data
(Revenue and Income for Trailing 12 Months, in Millions of $, except Employees)
COMPANY NAME |
MARKET CAP |
REVENUES |
INCOME |
EMPLOYEES |
Ipg Photonics Corp |
4,218.72 |
1,286.70 |
218.88 |
5,960 |
Coda Octopus Group Inc |
63.82 |
19.03 |
3.12 |
0 |
Esco Technologies inc |
2,670.93 |
967.19 |
92.99 |
3,254 |
Skywater Technology Inc |
459.98 |
286.68 |
-25.09 |
590 |
Applied Materials Inc |
172,614.51 |
26,485.00 |
7,158.00 |
33,000 |
Kla Corporation |
95,182.96 |
9,671.43 |
2,706.40 |
14,000 |
Agilent Technologies inc |
43,062.63 |
6,833.00 |
1,240.00 |
18,100 |
Atomera Incorporated |
144.22 |
0.52 |
-19.79 |
16 |
Lam Research Corporation |
128,460.99 |
14,315.39 |
3,458.21 |
17,700 |
Amkor Technology Inc |
7,777.88 |
6,502.15 |
362.13 |
29,300 |
Ase Technology Holding Co Ltd |
48,832.99 |
21,831.20 |
2,102.77 |
95,727 |
Formfactor inc |
3,404.54 |
662.58 |
82.39 |
1,685 |
Boeing Co |
116,845.72 |
77,794.00 |
-2,242.00 |
142,000 |
Honeywell International Inc |
137,107.97 |
36,662.00 |
5,672.00 |
99,000 |
Itt Inc |
11,258.13 |
3,283.00 |
413.80 |
9,400 |
Northrop Grumman Corp |
72,736.51 |
39,290.00 |
2,056.00 |
88,000 |
Textron Inc |
19,375.34 |
13,683.00 |
921.00 |
33,000 |
Lockheed Martin Corporation |
114,254.10 |
67,571.00 |
6,920.00 |
114,000 |
General Dynamics Corporation |
77,908.02 |
42,272.00 |
3,315.00 |
103,100 |
Eaton Corporation Plc |
125,461.88 |
23,196.00 |
3,223.00 |
85,947 |
Sai tech Global Corporation |
21.53 |
10.64 |
-8.85 |
0 |
Science Applications International Corporation |
7,004.06 |
7,704.00 |
303.00 |
13,000 |
Leidos Holdings Inc |
18,115.91 |
15,438.00 |
208.00 |
43,000 |
Astronics Corporation |
605.73 |
650.67 |
-40.18 |
2,000 |
Aerovironment Inc |
4,064.01 |
577.99 |
32.43 |
663 |
Cpi Aerostructures Inc |
29.04 |
85.41 |
9.27 |
0 |
Elbit Systems Ltd |
9,122.19 |
5,974.74 |
215.86 |
11,851 |
Kratos Defense and Security Solutions inc |
2,261.87 |
1,036.60 |
2.40 |
3,600 |
Sigma Additive Solutions Inc |
44.71 |
0.57 |
-7.30 |
0 |
Sifco Industries Inc |
18.94 |
85.97 |
-9.53 |
465 |
Panacea Life Sciences Holdings Inc |
1.35 |
1.75 |
-7.51 |
0 |
Bwx Technologies Inc |
9,197.32 |
2,496.31 |
246.32 |
5,300 |
Oshkosh Corporation |
7,926.10 |
9,393.90 |
522.30 |
13,300 |
Richardson Electronics Ltd |
112.85 |
247.37 |
17.24 |
373 |
Raven Industries Inc |
2,090.89 |
437.77 |
41.32 |
941 |
Uas Drone Corp |
4.36 |
0.00 |
-0.72 |
0 |
Aptiv Plc |
21,443.73 |
20,051.00 |
2,966.00 |
155,000 |
Johnson Controls International Plc |
44,417.60 |
26,273.00 |
1,994.00 |
102,000 |
China Automotive Systems inc |
96.64 |
515.49 |
14.48 |
4,230 |
Strattec Security Corp |
0.00 |
492.15 |
-8.95 |
3,877 |
Taitron Components Incorporated |
19.56 |
6.92 |
1.77 |
20 |
Autoliv Inc |
10,573.75 |
8,112.00 |
363.00 |
54,600 |
Cerner Corporation |
28,128.21 |
5,806.85 |
589.47 |
27,400 |
Danaher Corporation |
185,646.08 |
23,890.00 |
4,764.00 |
80,000 |
Intuitive Surgical Inc |
142,656.82 |
7,123.50 |
1,817.30 |
9,793 |
Medtronic Plc |
116,057.66 |
32,319.00 |
4,234.00 |
95,000 |
Roper Technologies Inc |
60,226.13 |
6,177.20 |
1,384.20 |
19,300 |
Thermo Fisher Scientific Inc |
225,524.53 |
42,857.00 |
5,955.00 |
130,000 |
Kulicke And Soffa Industries Inc |
2,770.75 |
737.45 |
51.85 |
2,778 |
Kopin Corporation |
200.77 |
41.22 |
-19.75 |
172 |
Osi Systems inc |
2,419.51 |
1,364.89 |
113.62 |
6,928 |
Park Aerospace Corp |
327.92 |
52.33 |
9.51 |
387 |
Surge Components Inc |
15.74 |
39.22 |
2.02 |
38 |
Trans lux Corporation |
0.00 |
17.38 |
-2.82 |
68 |
Tower Semiconductor Ltd |
3,623.87 |
1,677.61 |
266.47 |
5,641 |
Viavi Solutions Inc |
2,116.55 |
1,006.40 |
-29.10 |
3,500 |
Taiwan Semiconductor Manufacturing Company Limited |
703,350.20 |
73,670.40 |
32,323.30 |
45,272 |
Gilat Satellite Networks Ltd |
299.23 |
266.09 |
23.50 |
1,041 |
Iteris inc |
210.60 |
170.06 |
2.49 |
0 |
Dish Network Corporation |
3,081.38 |
15,616.45 |
1,303.29 |
14,500 |
Technical Communications Corporation |
0.65 |
0.35 |
-2.30 |
23 |
Viasat Inc |
2,143.14 |
3,226.46 |
316.68 |
5,200 |
Asml Holding Nv |
382,789.33 |
30,865.43 |
8,779.68 |
7,955 |
Wolfspeed Inc |
3,382.46 |
868.60 |
-620.40 |
4,017 |
Cohu Inc |
1,472.70 |
636.32 |
28.16 |
0 |
Airgain Inc |
56.74 |
64.85 |
-10.16 |
145 |
Bk Technologies Corporation |
199,105.13 |
74.09 |
-2.23 |
113 |
Onto Innovation Inc |
8,915.89 |
849.75 |
157.06 |
1,636 |
Camtek Ltd |
4,305.95 |
315.38 |
78.63 |
404 |
SUBTOTAL |
3,393,623.14 |
740,651.69 |
105,807.77 |
1,763,350 |
|