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Contradictions
Su-Field
Choose...
1 - Weight of moving object
2 - Weight of stationary object
3 - Lenght of a moving object
4 - Lenght of a stationary object
5 - Area of a moving object
6 - Area of a stationary object
7 - Volume of a moving object
8 - Volume of a stationary object
9 - Speed
10 - Force - intensity
11 - Stress or pressure
12 - Shape
13 - Stability of the object’s composition
14 - Strength
15 - Duration of action of moving object
16 - Duration of action of stationary object
17 - temperature
18 - Illumination intensity
19 - Use of energy by moving object
20 - Use of energy by stationary object
21 - Power
22 - Loss of energy
23 - Loss of substance
24 - Loss of information
25 - Loss of time
26 - Quantité of substance / the matter
27 - Reliability
28 - Measurement accuracy
29 - Manufacturing precision
30 - Object-affected harmful factors
31 - Object-generated harmful factors
32 - Ease of manufacture
33 - Ease of operation
34 - Ease of repair
35 - Adaptability or versality
36 - Device complexity
37 - Difficulty of detecting and measuring
38 - Extent of automation
39 - Productivitty
Choose...
1 - Weight of moving object
2 - Weight of stationary object
3 - Lenght of a moving object
4 - Lenght of a stationary object
5 - Area of a moving object
6 - Area of a stationary object
7 - Volume of a moving object
8 - Volume of a stationary object
9 - Speed
10 - Force - intensity
11 - Stress or pressure
12 - Shape
13 - Stability of the object’s composition
14 - Strength
15 - Duration of action of moving object
16 - Duration of action of stationary object
17 - temperature
18 - Illumination intensity
19 - Use of energy by moving object
20 - Use of energy by stationary object
21 - Power
22 - Loss of energy
23 - Loss of substance
24 - Loss of information
25 - Loss of time
26 - Quantité of substance / the matter
27 - Reliability
28 - Measurement accuracy
29 - Manufacturing precision
30 - Object-affected harmful factors
31 - Object-generated harmful factors
32 - Ease of manufacture
33 - Ease of operation
34 - Ease of repair
35 - Adaptability or versality
36 - Device complexity
37 - Difficulty of detecting and measuring
38 - Extent of automation
39 - Productivitty
Determine the type of problem
Measurement or detection problem
Evolution problem (product/system/performance)
advanced search
Principle
IP 1 Segmentation
IP 2 Taking Away
IP 3 Local Quality
IP 4 Asymmetry
IP 5 Combining
IP 6 Universality
IP 7 Nested Doll
IP 8 Anti-Weight
IP 9 Prior Counteraction
IP 10 Prior Action
IP 11 Beforehand Cushioning
IP 12 Equipotentiality
IP 13 Other Way Round
IP 14 Spheroidality
IP 15 Dynamicity
IP 16 Partial or Excessive Action
IP 17 Another Dimension
IP 18 Mechanical Vibration
IP 19 Periodic Action
IP 20 Useful Action Continuity
IP 21 Skip
IP 22 Turn the Harm to One’s Good
IP 23 Feedback
IP 24 Intermediary
IP 25 Self-Service
IP 26 Use of Copies (Copying)
IP 27 Cheap Short-Life Instead of Costly Long-Life
IP 28 Mechanical Principle Replacement
IP 29 Pneumatic and Hydraulic Structures
IP 30 Flexible Shells and Thin Films
IP 31 Porous Materials
IP 32 Changing Color
IP 33 Homogeneity
IP 34 Rejecting and Regeneration of Parts
IP 35 Change of Physical and Chemical Parameters
IP 36 Phase Transitions
IP 37 Thermal Expansion
IP 38 Strong Oxidizers (Strong Oxidents)
IP 39 Inert Atmosphere
IP 40 Composites
Standard
Synthesis and decomposition of the SFM
Synthesis of SFM
IS 1.1.1 Synthesis of SFM
IS 1.1.2 Transition to internal complex SFM
IS 1.1.3 Transition to external complex SFM
IS 1.1.4 Transition to SFM by using external environment
IS 1.1.5 Transition to SFM by using external environment with additives
IS 1.1.6 Minimum mode of action
IS 1.1.7 Maximum mode of action
IS 1.1.8 Selective-maximum mode
Decomposition of SFM
IS 1.2.1 Elimination of harmful interaction by introducing foreign substance
IS 1.2.2 Elimination of harmful interaction by modification existing substances
IS 1.2.3 Drawing of harmful action of the field
IS 1.2.4 Counteraction for harmful actions through the field
IS 1.2.5 'Disconnection' of magnetic interactions
Evolution of SFM
Transition to complex SFM
IS 2.1.1 Transition to chain SFM
IS 2.1.2 Transition to dual SFM
Evolution of SFM
IS 2.2.1 Transition to more controlled fields
IS 2.2.2 Segmentation of tool
IS 2.2.3 Transition to capillary porous substance
IS 2.2.4 Increasing the degree of dynamism of SFM
IS 2.2.5 Structuring of field
IS 2.2.6 Structuring of substance
Evolution by coordinating rhythms
IS 2.3.1 Matching of rhythm of field and product (or tool)
IS 2.3.2 Matching of rhythm of fields
IS 2.3.3 Coordination of the incompatible or independent actions
Complex-forced SFM
IS 2.4.1 Transition to a ferromagnetic substance and a magnetic field
IS 2.4.2 Transition to a ferromagnetic substance
IS 2.4.3 Using of magnetic fluids
IS 2.4.4 Capillary porous structure of ferromagnetic SFM
IS 2.4.5 Transition to complex ferromagnetic SFM
IS 2.4.6 Transition to ferromagnetic SFM in the external environment
IS 2.4.7 Using physical effects
IS 2.4.8 Increasing the degree of dynamism of feSFM
IS 2.4.9 Structuring of feSFM
IS 2.4.10 Matching the rhythms into feSFM
IS 2.4.11 Transition to electrical SFM
IS 2.4.12 Applying electrorheologic fluid
Transition to super-system and micro-level
Transition to bi- and poly-systems
IS 3.1.1 Transition to bisystems and polysystems
IS 3.1.2 Developing interactions in bi- and polysystems
IS 3.1.3 Increasing the difference between systems components for bi- and polysystems
IS 3.1.4 Convergence of bi- and polysystem
IS 3.1.5 Incompatible properties of system and its parts
Transition to micro-level
IS 3.2.1 Transition to microlevel
Measurement and detection standards
Bypass ways
IS 4.1.1 Instead of measurement and detection – system change
IS 4.1.2 Using of copies
IS 4.1.3 Successive detection of changes
Synthesis of measurement system
IS 4.2.1 Synthesis of measurement SFM
IS 4.2.2 Transition to complex measuring SFM
IS 4.2.3 Transition to external complex measuring SFM
IS 4.2.4 Transition to measurement SFM by using external environment properties
Improvement of measurement systems
IS 4.3.1 Using physical effects
IS 4.3.2 Using resonance oscillation of object
IS 4.3.3 Using resonance oscillation of connected object
Transition to ferromagnetic measurement systems
IS 4.4.1 Transition to ferromagnetic substance and magnetic fields
IS 4.4.2 Transition to measurement feSFM
IS 4.4.3 Transition to complex ferromagnetic SFM
IS 4.4.4 Transition to measurement feSFM by using external environment properties
IS 4.4.5 Using physical effects for measurement feSFM
Evolution of measurement systems
IS 4.5.1 Transition to a measuring bi- and polysystems
IS 4.5.2 Transition to measurement the derivatives of function
Helpers (standards for applying the standards)
Substance introduction
IS 5.1.1 Bypass ways
IS 5.1.2 Dividing of product
IS 5.1.3 Self-maintained getting out of used substances
IS 5.1.4 Using of inflatable structures
Introduction of fields
IS 5.2.1 Using present fields (pluralistically)
IS 5.2.2 Using fields from external environment
IS 5.2.3 Using substances as resources of fields
Use of phase transition
IS 5.3.1 Changing of phase state
IS 5.3.2 'Dual' phase state of substance
IS 5.3.3 Using phenomena accompanying a phase transition
IS 5.3.4 Transition to dual-phase state
IS 5.3.5 Using interaction between phases of the system
Physical effects applying
IS 5.4.1 Using reversible physical transformation
IS 5.4.2 Amplification of field at the output
Substance particles obtaining (experimental standards)
IS 5.5.1 Substance particles obtaining by decomposition
IS 5.5.2 Substance particles obtaining by completing or combining
IS 5.5.3 Simple methods for substance particles obtaining
Separation method
SM 1 Separation of conflicting properties in space
SM 2 Separation of conflicting properties in time
SM 3 Combination of homogeneous or heterogeneous systems into a super-system
SM 4 Transition from a system to an anti-system, or combination of system with anti-system
SM 5 The entire system has a property X while its parts have a property opposite to X (anti-X)
SM 6 System transition 2: transition to system that works on the micro-level
SM 7 Substitution of the phase state of a system’s part or external environment
SM 8 Dual phase state of a system part (using substances capable of converting from one phase to another according to operating conditions)
SM 9 Using of phenomena associated with phase transitions
SM 10 Substitution of a mono-phase substance with a dual-phase state
SM 11 Substance appearance-disappearance as a result of decomposition-combination, ionization-recombination
Law
Law 1 System completeness
Law 2 Energy conductivity
Law 3 Harmonization
Law 4 Increasing Ideality
Law 5 Irregularity of system's part evolution
Law 6 Transition to the super system
Law 7 Transition from macro to micro level
Law 8 Dynamic growth
Law 9 Increasing su-field interactions
Principle
Standard
Separation mehtod
Law
Computer generated
Human generated
Change links threshold
0.8
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