1. A nonaqueous electrolyte secondary battery comprising a positive electrode, a negative electrode, a nonaqueous electrolyte, and a separator,
wherein the positive electrode includes a positive electrode current collector, a positive electrode active material layer, and a carbon layer provided between the positive electrode current collector and the positive electrode active material layer; and
the positive electrode active material layer contains a lithium composite oxide with a molar ratio of nickel to manganese (nickelmanganese) of 64 or more.
2. The nonaqueous electrolyte secondary battery according to claim 1, wherein the amount of a water-soluble alkali component in the lithium composite oxide is 0.15% by mass or more.
3. The nonaqueous electrolyte secondary battery according to claim 1, wherein the lithium composite oxide is a compound represented by the general formula: LiaNixMn1-xO2 (0.6\u2266x\u22660.9, 1.03\u2266a\u22661.2).
4. The nonaqueous electrolyte secondary battery according to claim 1, wherein the positive electrode current collector contains aluminum.
5. The nonaqueous electrolyte secondary battery according to claim 1, wherein the thickness of the carbon layer is 10 \u03bcm or less.
The claims below are in addition to those above.
All refrences to claim(s) which appear below refer to the numbering after this setence.
1. A method of driving light controlling apparatus which includes a substrate, which has an aperture, a plurality of incident-light controlling units, each having an aperture of different diameter formed thereon, which are displaced on the substrate, a plurality of driving unit which exert on the incident-light controlling unit, an aperture-displacing driving force which displaces the incident-light controlling unit to an aperture position, and a retracting-displacement driving force which displaces the incident-light controlling unit to a retracted position which is different from the aperture position, the incident-light controlling unit is displaced by the driving unit to the aperture position and the retracted position alternately, and incident light passing through the aperture is adjusted, and when one incident-light controlling unit is at the aperture position, the remaining incident-light controlling units are displaced to the retracted position, each of the plurality of incident-light controlling units having a non-coincident axis of rotation, comprising:
a step of displacing the incident-light controlling unit, which includes a step of displacing a first incident-light controlling unit disposed at the aperture position, to the retracted position, and a step of displacing a second incident-light controlling unit disposed at the retracted position, to the aperture position, after completion of the step of displacing the first incident-light controlling unit to the retracted position.
2. The method of driving light controlling apparatus according to claim 1, further comprising: a step of releasing the retracting-displacement driving force of the driving units corresponding to all the incident-light controlling unit disposed at the retracted position, after completion of the step of displacing the second incident-light controlling unit disposed at the retracted position, to the aperture position.
3. The method of driving light controlling apparatus according to claim 2, further comprising: a step of exerting the retracting-displacement driving force of the driving units corresponding to all incident-light controlling unit disposed at the retracted position, prior to the step of displacing the first incident-light controlling unit disposed at the aperture position, to the retracted position.
4. The method of driving light controlling apparatus according to claim 3, further comprising: a step of reducing the aperture-displacing driving force of the driving unit corresponding to the incident-light controlling unit disposed at the aperture position after the step of displacing the second incident-light controlling unit disposed at the retracted position, to the aperture position.
5. The method of driving light controlling apparatus according to claim 4, wherein the aperture-displacing driving force and the retracting-displacement driving force include an operating driving force which displaces the position of the incident-light controlling unit and a maintaining driving force which maintains the position of the incident-light controlling unit, and the operating driving force is stronger than the maintaining driving force.
6. The method of driving light controlling apparatus according to claim 5, wherein at the time of putting ON a power supply of the light controlling apparatus, all the incident-light controlling unit are displaced to the retracted position.
7. The method of driving light controlling apparatus according to claim 6, wherein the plurality of incident-light controlling unit are displaced in a same plane.
8. The method of driving light controlling apparatus according to claim 7, wherein the operating driving force is in a form of a sinusoidal wave.
9. A control unit of light controlling apparatus, which drives a light controlling apparatus according to claim 8, generates the aperture-displacing driving force and the retracting-displacement driving force, and exerts the aperture-displacing driving force and the retracting-displacement driving force to the incident-light controlling unit.
10. The method of driving light controlling apparatus according to claim 7, wherein the maintaining driving force is exerted intermittently to the incident-light controlling unit.
11. A control unit of light controlling apparatus which drives a light controlling apparatus according to claim 10, generates the aperture-displacing driving force and the retracting-displacement driving force, and exerts the aperture-displacing driving force and the retracting-displacement driving force to the incident-light controlling unit.
12. The method of driving light controlling apparatus according to claim 6, wherein
each of the plurality of incident-light controlling unit is displaced in a different plane, and
a regulating member which regulates the displacement of the other incident-light controlling unit to the aperture position is formed in each incident-light controlling unit.
13. The method of driving light controlling apparatus according to claim 12, wherein the operating driving force is in a form of a sinusoidal wave.
14. A control unit of light controlling apparatus which drives a light controlling apparatus according to claim 13, generates the aperture-displacing driving force and the retracting-displacement driving force, and exerts the aperture-displacing driving force and the retracting-displacement driving force to the incident-light controlling unit.
15. The method of driving the light controlling apparatus according to claim 12, wherein the maintaining driving force is exerted intermittently to the incident-light controlling unit.
16. A control unit of light controlling apparatus which drives a light controlling apparatus according to claim 15, generates the aperture-displacing driving force and the retracting-displacement driving force, and exerts the aperture-displacing driving force and the retracting-displacement driving force to the incident-light controlling unit.
17. A light controlling apparatus comprising:
a substrate, which has an aperture;
a plurality of incident-light controlling unit which are displaced on the substrate, each of the plurality of incident-light controlling unit having a non-coincident axis of rotation;
a plurality of driving unit which exert on the incident-light controlling unit, an aperture-displacing driving force which displaces the incident-light controlling unit to an aperture position, and a retracting-displacement driving force which displaces the incident-light controlling unit to a retracted position which is different from the aperture position; and
a detecting section which detects a state of the incident-light controlling unit, wherein
based on a result of detection by the detecting section, the incident-light controlling unit is displaced by the driving unit to the aperture position and the retracted position alternately, and incident light passing through the aperture is adjusted, and the displacement of each incident-light controlling unit to the aperture position is exclusive for the other incident-light controlling unit.
18. The light controlling apparatus according to claim 17, wherein an aperture of different diameter is formed in each incident-light controlling unit.
19. The light controlling apparatus according to claim 17, wherein a different optical lens is formed for each incident-light controlling unit.
20. The light controlling apparatus according to claim 17, wherein a different optical filter is formed for each incident-light controlling unit.
21. A method of driving light controlling apparatus which includes a substrate, having an aperture, a plurality of incident-light controlling units, each having a different optical lens formed thereon, which are displaced on the substrate, a plurality of driving unit which exert on the incident-light controlling unit, an aperture-displacing driving force which displaces the incident-light controlling unit to an aperture position, and a retracting-displacement driving force which displaces the incident-light controlling unit to a retracted position which is different from the aperture position, the incident-light controlling unit being displaced by the driving unit to the aperture position and the retracted position alternately, and incident light passing through the aperture is adjusted, and when one incident-light controlling unit is at the aperture position, the remaining incident-light controlling units are displaced to the retracted position, each of the plurality of incident-light controlling units having a non-coincident axis of rotation, comprising:
a step of displacing the incident-light controlling unit, which includes a step of displacing a first incident-light controlling unit disposed at the aperture position, to the retracted position, and a step of displacing a second incident-light controlling unit disposed at the retracted position, to the aperture position, after completion of the step of displacing the first incident-light controlling unit to the retracted position.
22. A method of driving light controlling apparatus which includes a substrate, having an aperture, a plurality of incident-light controlling units, each having a different optical filter formed thereon, which are displaced on the substrate, a plurality of driving unit which exert on the incident-light controlling unit, an aperture-displacing driving force which displaces the incident-light controlling unit to an aperture position, and a retracting-displacement driving force which displaces the incident-light controlling unit to a retracted position which is different from the aperture position, the incident-light controlling unit being displaced by the driving unit to the aperture position and the retracted position alternately, and incident light passing through the aperture is adjusted, and when one incident-light controlling unit is at the aperture position, the remaining incident-light controlling units are displaced to the retracted position, each of the plurality of incident-light controlling units having a non-coincident axis of rotation, comprising:
a step of displacing the incident-light controlling unit, which includes a step of displacing a first incident-light controlling unit disposed at the aperture position, to the retracted position, and a step of displacing a second incident-light controlling unit disposed at the retracted position, to the aperture position, after completion of the step of displacing the first incident-light controlling unit to the retracted position.