TPP DLW專利分析期末報告HW_6
Members : 芮嘉瑋
鄭郁彬
Advisor : 張瑞芬 特聘教授
12015/7/29
Advanced LIGA MEMS Lab
Process of Patent Analysis
1. 專利分析主題及其分析目的
•分析的技術領域
•專利分析的目的
2. 專利檢索策略與流程
•專利資料庫及檢索範圍
•檢索關鍵字的邏輯
•專利檢索策略與流程
•專利檢索結果
•專利分析流程架構與策略
3. 專利管理圖分析
•歷年專利活動分析
•發明人分析
•專利權人分析
•引證分析
4. 專利技術圖分析
•TPP DLW技術的專利分
類號
•重要專利權人歷年技術發展趨勢
•權利範圍(claim)人工解析魚骨分群
•分群依據
5. 重要廠商專利佈
局策略
•TOP assignee布局策略
•潛在競爭者的布局監控
6. 結論與佈局建議
•Correspond with the purpose of patent analysis
•專利佈局建議
Advanced LIGA MEMS Lab
Outline
• Patent Analysis of Top 5 Assignees• Patent Analysis of Potential Competitors• Nanoscribe Gmbh• Technische Universität Ilmenau• Purdue Research Foundation• Technion Research & Development Foundation Limited
• Principle of Cluster • Organize fish-bone figure and overview of that• Representative patent for each clustering• Technology - Function Clustering• Correspond with the purpose of patent analysis• Clustering by Algorithm
Advanced LIGA MEMS Lab
Outline
• Principle of Cluster
• Organize fish-bone figure and overview of that
• Representative patent for each clustering
• Technology - Function Clustering
• Correspond with the purpose of patent analysis
Advanced LIGA MEMS Lab
Cluster according to the claim analysis
Claim Analysis
Annotate each element in
independent claim
Identify patentable feature
Highlight patentable feature with one
sentence
Cluster and definition
Advanced LIGA MEMS Lab
Outline
• Principle of Cluster
• Organize fish-bone figure and overview of that
• Representative patent for each clustering
• Technology - Function Clustering
• Correspond with the purpose of patent analysis
Advanced LIGA MEMS Lab
TPP DLW
Photoniccrystal
Method
structureControldefect
Optical device
Type of surface of emission face
Light guides
Microlensarrays
nonsphericalmicrolense
truncated aspheric Geometric configuration
Organize fish-bone figure
Biotechnology(Health)
biological tissue
closing bleeding wound
surgery
photoreactive composition(Material)
inorganic particles
multi-photon photoinitiatorsystem
multi-photon photosensitizer
composition
electron acceptor
reactive species
Particle size
solubility
Volume %
electron Donor(optional)
photoinitiator
Bio-imagingtechnique
for detecting protein crystals
emission spectrum
diagnosisin vivo diagnosis or testing
medicine
pharmaceutical composition
Image system
apparatus
multiphoton microscopy
temporal focusingbased
having a prismatic optical element
microscopy confocal microscopy
focusing
endoscopy
Optical data storage medium
Beam energy control
exposure
optical recording material
iodonium salts, sulfonium salts
autofocus means function
Modeling(Microfabrication)
3D Print(layer-by-layer)
Single step
Multi-beaminterference
Advanced LIGA MEMS Lab
Modeling(Microfabrication)
Technology Clustering
3D Printing (Additive manufacture,
layer by layer)
BiotechnologyUS20140142914
Layer thicknessUS20130286485
micro opticsmicro lense
US20130286485
integrates two-photon lithography and nanoimprinting
US20110046764US20120325775
process
structure
Tissue engineering
ScaffoldsUS20110046764
Cell growthUS7718351
US20100240117
artificial organUS20100240117
US8852932
Pores dimensionUS7718351,
US20100240117
materialPores material
US20100240117
Blood vesselsUS20080228455
Single step
Advanced LIGA MEMS Lab
Advanced LIGA MEMS Lab
Outline
• Principle of Cluster
• Organize fish-bone figure and overview of that
• Representative patent for each clustering
• Technology - Function Clustering
• Correspond with the purpose of patent analysis
Advanced LIGA MEMS Lab
Representative patent for each clustering
Advanced LIGA MEMS Lab
Outline
• Principle of Cluster
• Organize fish-bone figure and overview of that
• Representative patent for each clustering
• Technology - Function Clustering
• Correspond with the purpose of patent analysis
Advanced LIGA MEMS Lab
Technology - Function Clustering
TPP DLW技術
Image system
ModelingOptical device
TPP DLW功效
StabilityHigh spatial resolution
Simplified process
MaterialPhotoniccrystal
Biotechnology
Reduce writing time
Machining accuracy
High energydensity
Low cost Enhancingimage contrast
Advanced LIGA MEMS Lab
Preparation of Technology-Function Matrix
Advanced LIGA MEMS Lab
TPP DLW Technology-Function Matrix
Technology -Function
T1-Image system T2-Modeling T3-Optical device T4-Material T5-Photonic crystal T6-Biotechnology
T1-1 T1-2 T2-1 T2-2 T3-1 T3-2 T3-3 T4-1 T4-2 T4-3 T5-1 T5-2 T6-1 T6-2 T6-3
microscopy apparatus3D Print(layer by
layer)
Single step Microlens
arrays
Optical data storage medium
Light guidesreactive species
multi-photon photoinitiator
system inorganic particles
structure Method diagnosisBio-
imagingtechnique
biological tissue
F1Stability
16 9 2 6 4 5 2 5 3 5 0 1 0 3 4
F2High spatial resolution
28 11 2 9 5 8 3 1 1 2 1 1 2 3 5
F3Simplified process
1 2 2 4 2 4 4 4 4 2 0 2 1 0 0
F4Reduce writing time
2 1 1 5 3 5 2 5 2 1 2 1 1 2 1
F5Machining accuracy
23 6 2 6 5 6 3 0 1 3 3 0 0 1 2
F6High energy density
14 2 0 4 2 3 1 2 3 4 2 1 2 3 2
F7Low cost
4 2 1 0 1 2 0 6 10 6 1 0 1 0 0
F8Enhancing image contrast
9 6 0 1 1 0 1 5 1 3 0 0 2 7 6
Advanced LIGA MEMS Lab
Advanced LIGA MEMS Lab
Methods of fabricating electronic and mechanical structures US 20140231266 A1
Assignees: Nuvotronics, LLC
1. A method of fabricating three dimensional structures, comprising: a) selectively depositing at least one dielectric material comprising a metallizable composition onto a substrate using three dimensional printing, andb) selectively depositing metal onto the dielectric material comprising a metallizable composition.2. The method of claim 1, wherein the three dimensional printing is at least one of stereolithography, 2-photon stereolithography, inkjet, hot melt extrusion fabrication, or selective laser sintering.3. The method of claim 1, wherein at least one of the deposited dielectric materials that comprise a metallizable composition further comprises a photoimageable dielectric composition.
Advanced LIGA MEMS Lab
3D Mold For Manufacturing Of Sub-Micron 3D Structures Using 2-D Photon Lithography And Nanoimprinting And Process Thereof
US 20110046764 A1
1. A process of manufacturing a 3D mold to fabricate a high-throughput and low cost sub-micron 3D structure product, said process integrating 2-photon lithography and nanoimprinting, comprising using 2-photon laser lithography and 3D write technology to make a 3D mold of each layer of the 3D structure product, using nanoimprinting to form a sheet of polymer film of each layer of the 3D structure from said 3D mold of that layer, and fabricating each layer to make the sub-micron 3D structure product.2. A 3D mold of a layer of a high-throughput and low cost sub-micron 3D structure product, wherein the 3D mold of the layer is created by a process comprising using 2-photon laser lithography and 3D write technology to make a 3D mold of each layer of the 3D structure product and using nanoimprinting to form a sheet of polymer film of each layer of the 3D structure to make the 3D mold of that layer of the sub-micron 3D structure product.3. A 3D mold of a layer of a high-throughput and low-cost sub-micron 3D structure product using a process which integrates 2-photon lithography and nanoimprinting, wherein the 3D mold of the layer is manufactured by a process comprising: creating a design of a 3D layer of the 3D structure;setting up a writing process to produce an 3D image of the layer of the 3D structure product using a 2-photon lithography tool;developing a photo resist/polymer of the 3D image of the layer on a substrate;sputtering one or more layers of metal onto the surface of the photoresist/polymer of the 3D image of the layer to form a seed metal layer; andtransferring the 3D polymer image coated with the seed metal layer by an electroplating process to form a 3D metal mold;wherein the 3D metal mold is used to manufacture a copy of the 3D image of the same layer of the 3D structure product.
Advanced LIGA MEMS Lab
3D Mold For Manufacturing Of Sub-Micron 3D Structures Using 2-D Photon Lithography And Nanoimprinting And Process Thereof
US 20130286485 A1
1. A micro-lens having a curved surface, wherein said curved surface is not limited by surface tension properties of a liquid used to make said micro-lens.2. The micro-lens of claim 1, wherein said surface is contoured to focus, reflect, guide and bend light.3. The micro-lens of claim 1, wherein said curved surface is non-spherical.4. The micro-lens of claim 1, wherein said curved surface is asymmetric.5. A 3D structure comprising a plurality of layers bonded together wherein each of said plurality of layers has a thickness of between 0.01 micron and 150 microns.8. The 3D structure of claim 5, wherein said structure comprises a scaffold.9. The 3D structure of claim 8, wherein said scaffold comprises a synthetic material10. The 3D structure of claim 8, wherein said scaffold comprises a biological material.11. The 3D structure of claim 8, wherein said structure comprises a tissue scaffold.12. The 3D structure of claim 8, wherein said structure comprises an organ scaffold.13. The 3D structure of claim 12, wherein said structure comprises an organ scaffold for a kidney.14. The 3D structure of claim 12, wherein said structure comprises an organ scaffold for a liver.
Advanced LIGA MEMS Lab
Method for a layer-wise manufacturing of a three-dimensional object US 9011982 B2
• 1. A method for a layer-wise manufacturing of a three-dimensional object, the method comprising the following steps:
• a first step of providing a layer of a material in a powder form onto a support or onto a prior layer;• a second step of directing a focussed electromagnetic radiation or a focussed particle beam
selectively onto selected positions of the layer;• wherein, in the second step, the focussed electromagnetic radiation or particle beam is selected
such that it induces a change of the absorption of the material when hitting the layer at the selected positions without complete melting or sintering; and
• after the second step, carrying out a third step, which is discrete from the second step, of completely melting or sintering the layer at those positions of the layer that correspond to the cross-section of the object to be formed using an electromagnetic radiation that is different from the focussed electromagnetic radiation or particle beam of the second step,
• wherein the first to third steps are repeatedly carried out until the object is completed, and• wherein the solidification in the third step is effected at those selected positions at which the
focussed electromagnetic radiation or particle beam had been directed in the second step.
Advanced LIGA MEMS Lab
Citation Analysis
Page. 21/4
不一定有關聯
Advanced LIGA MEMS Lab
Correspond with the purpose of patent analysis
R&D Strategy and Market Opportunity 建立分群依據、掌握技術魚骨、洞悉定位、研
擬未來研發方向或技術預測。 掌握專利技術應用領域及其市場機會。
Knows the
status of art對該技術領域的全貌、技術子領域之技術分布及技術發展所處階段有全盤瞭解
Monitor trend
in art針對技術成長階段、技術遞移關係及技術發展方向來分析,以達到監控技術領域趨勢的目的
Monitor (potential)
competitor
藉由各技術分類歷年技術走向洞悉競爭者技術發展趨勢,進而了解重要廠商專利布局及其趨勢預測
Domain specific
patent analysis˙申請專利範圍分析˙法律狀態分析˙ Patent Valuation(option)
Advanced LIGA MEMS Lab
Cluster according to the claim analysis
Claim Analysis
Parse each element in independent
claim
Identify patentable feature
Highlight patentable feature with one
sentence
Cluster and definition
Advanced LIGA MEMS Lab
Modeling(Microfabrication)
Technology Clustering
3D Printing (Additive manufacture,
layer by layer)
BiotechnologyUS20140142914
Layer thicknessUS20130286485
micro opticsmicro lense
US20130286485
integrates two-photon lithography and nanoimprinting
US20110046764US20120325775
process
structure
Tissue engineering
ScaffoldsUS20110046764
Cell growthUS7718351
US20100240117
artificial organUS20100240117
US8852932
Pores dimensionUS7718351,
US20100240117
materialPores material
US20100240117
Blood vesselsUS20080228455
Single step
Advanced LIGA MEMS Lab
Outline
• Patent Analysis of Top 5 Assignees• Patent Analysis of Potential Competitors• Nanoscribe Gmbh• Technische Universität Ilmenau• Purdue Research Foundation• Technion Research & Development Foundation Limited
• Principle of Cluster • Organize fish-bone figure and overview of that• Representative patent for each clustering• Technology - Function Clustering• Correspond with the purpose of patent analysis• Clustering by Algorithm
系統分群方法
PATENT NUMBER/KEY TERM
20020001089… US8969219 NTF NTF-IDF Rate(%)
2-d 0 … 0 82.23 81.4077 1
3-dimensional 0 … 0 86.2 84.476 2
ablation 0 … 0 164.92 158.323 4
… … … … … … …
Patent Import
專利匯入
TF-IDF
詞頻逆向文詞頻解析
Modifying Term
調整關鍵字詞
K-means Analyzing
K-means方法解析
Grouping Analyzing
群組分析
類群化
Clustering_Number RMSSTD
1/RS Sum
2 3.2891 108.696
111.985
3 3.1706 11.8624
15.033
4 3.1606 10.5263
13.6869
分類分群
Advanced LIGA MEMS Lab
Patent Pool
402
OthersMethod(CMP)
化學機械平坦化
20090311955
US7377840
US8287793
US8932116
2D
3D+2D
US6027855Optical Recording
Material
RFID US7681301
Tissue
US5853370 US6397099 US6544794
US6745067 US7372985 US7711410
US7724937 US7805183 US8144966
US8221480 US8351675 US8712012
US8771978
imaging
chemical
US8828355
US8634131
US7938980
US8629197
Recording
Masterforms
US7312021 US7542186
US7803514 US8227150
US8609013 US8642991
US8004767
US7583444
metal optical
grayscale mask
Photoeractive
Recording Method
US7232913
US7282320
USS7285363
US7928222
US8207330
US7778723
US7790353
US8404173
US8133642
Recording device
Detecting Method
Display System
Photographic
US7969646
US8445178
US7848205
US7560869
US7728295
Plasmon
Nanoparticle
containing
precursors
Laser radiation/
Femtosecond
System and
MethodTomography
US7568365
US8279903
US8599658
US7252699
US8557017
US8779030
US7462496
US7492458
Microscope
Method
Process
Counterfeiting
protection
High resolution
microscope
imaging or cutting
in laser endoscopy
US8183531
US8718351 US8487271 US8389893
US8183531 US7902526 US7872748
US7642536 US7342717 US7304745
48
US7936956
US7642509
US7815117
US7757952
US8496579
Surface
Modification
Short wavelength coherence
tomography
Optical information device
US7943533
US7656538
US8031577
比較分析
TPP
DLW
Image
System
Optical
Device
Photoni
c Crystal
Photoreactive
composition
(Material)
Exposur
e
apparat
us
Light
Guide
Microle
ns
arrays
truncated aspheric Geometric configuration
nonspherical microlense
Type of surface of emission face
Method
Structur
e
controlled defect
Inorgani
c
Particles
Reactive
Species
Multi-photon
photoinitiator system
iodonium salts, sulfonium salts
having a two-photon absorption cross-section greater than that of fluorescein;
multi-photon photosensitizer
photoinitiator
electron acceptor
electron Donor(optional)
composition
solubility
Particle size
Volume %
US7583444US8004767
US7583444US8004767US7941013US7936956