Patent Description:
A background art related to the present invention is disclosed in Patent Literature <NUM>. According to a configuration disclosed in Patent Literature <NUM>, a diffraction lens using high-order diffracted light is used as a camera or projector lens in order to reduce the thickness of the lens without sacrificing the optical performance of the lens. Further, Patent Literature <NUM> indicates that the diffraction lens is also applicable to a vehicular lamp.

Meanwhile, according to a configuration disclosed in Patent Literature <NUM>, a Fresnel lens is used in order to reduce the overall length of a vehicular lamp. Further, according to a configuration disclosed in Patent Literature <NUM>, a diffraction lens is used as an optical disk objective lens in order that the lens is shared by a plurality of wavelengths.

<CIT> and <CIT> disclose relevant prior art.

It is demanded that a lens used for a vehicular headlight be thin and able to form a proper image of a cut-off line during low-beam radiation.

The diffraction lens described in Patent Literature <NUM> is a meniscus lens (a lens having a concave surface and a convex surface having a greater curvature than the concave surface). Thus, the lattice plane of the diffraction lens is easily deformed by stress generated during a mold release and cooling process for molding. As a result, when the diffraction lens is used for a vehicular lamp, the cut-off line of a low beam may be improperly imaged (in terms of contrast).

The lens described in Patent Literature <NUM> is a vehicular lens. However, as a Fresnel lens is used as the vehicular lens, the cut-off line of a low beam may not be adequately imaged. Here, the Fresnel lens is obtained by dividing a uniform, continuous, curved lens surface into equal intervals radially from an optical axis into the plane or dividing the height of the surface into equal intervals in the direction of the optical axis, and reducing the thickness of the lens by cutting to uniform the height of the surface in the optical axis direction while maintaining the shape of the divided surface. Consequently, it is difficult to simultaneously satisfy the requirements on the shape of an envelope surface for acquiring desired lens characteristics and the requirements on a phase function for prescribing the lens power.

The lens described in Patent Literature <NUM> is not a vehicular lens, but is an optical disk lens. However, this lens is well known as a diffraction lens and has a function for forming an image of an information recording surface on a sensor. This diffraction lens uses first-order diffracted light in order for the use of laser light having a plurality of wavelengths. However, when this diffraction lens is used for white light of a vehicular headlight, a problem occurs due, for instance, to a decrease in diffraction efficiency or the generation of stray light from unnecessary high-order diffracted light.

An object of the present invention is to provide a highly-moldable, thin diffraction lens that is used for a vehicular lamp using a white light source and capable of properly forming an image of a cut-off line of a low beam. Solution to Problem.

According to an aspect of the present invention, there is provided a diffraction lens. A light beam incident side and exit side of the diffraction lens are both convexly shaped. An exit diffraction plane having an absolute value for the order of diffraction of <NUM> or greater is disposed on the exit side. The diffraction lens is shaped such that the absolute value of a curvature at the surface apex of an envelope surface of the exit diffraction plane is smaller than the absolute value of a curvature at the surface apex of an incident surface, or the absolute value of the amount of sag in the direction of the optical axis at an outer periphery of the envelope surface of the exit diffraction plane is smaller than the maximum absolute value of the amount of sag in the direction of the optical axis at an outer periphery of the incident surface. Advantageous Effects of Invention.

The present invention provides a highly-moldable, thin diffraction lens that is used for a vehicular lamp using a white light source and capable of properly forming an image of a cut-off line of a low beam.

Examples of the present invention will now be described with reference to the accompanying drawings. Examples <NUM> to <NUM> describe the shape of a diffraction lens that delivers suitable optical performance (light distribution) during low-beam radiation. Example <NUM> describes a configuration of a vehicular lamp that uses a diffraction lens.

<FIG> is a side view illustrating the shape of a diffraction lens according to Example <NUM>. <FIG> is a diagram illustrating, in tabular form, exemplary dimensional specifications for the diffraction lens.

Referring to <FIG>, incident light beams <NUM> from a virtual light source <NUM> enter a left-side incident surface <NUM> of a diffraction lens <NUM>, and exit from a right-side exit surface as substantially parallel light beams. As described later, a shade is disposed at the position of the virtual light source <NUM>. The shade is a cover that forms a cut-off line during low-beam radiation from an automotive headlight. The shape of the diffraction lens <NUM> is designed such that an image of the shadow of an edge of the shade is formed at infinity (substantially at a location farther than a dozen meters away).

A zonal diffraction lens surface <NUM> (referred to also as the exit diffraction plane) is disposed on an exit surface <NUM> of the diffraction lens <NUM>. The diffraction lens surface <NUM> has surface irregularity that is centered around an optical axis <NUM> and substantially parallel to the optical axis <NUM>. The diffraction lens surface <NUM> is designed such that its comprehensive shape is defined by the shape of an envelope surface <NUM> along the central position of the surface irregularity, and that a predetermined optical path difference is given to a light beam transmitted through zonal bands on both sides divided by the surface irregularity.

As indicated in <FIG>, Example <NUM> is configured such that 40th-order diffracted light (high-order diffracted light) achieves a diffraction efficiency of approximately <NUM>% at a designed center wavelength of <NUM>. A condition for such diffraction is given such that the optical path difference of vertical incident light is (n - <NUM>) d/λ where n is a refractive index and d is the surface irregularity and λ is the wavelength of the light. The diffraction condition is satisfied when the optical path difference is <NUM> times the wavelength. More specifically, as acrylic resin having a refractive index of <NUM> at the abovementioned center wavelength is used as a lens material, the above diffraction efficiency is achievable when the surface irregularity d is approximately <NUM>. As the surface irregularity for providing the above optical path difference varies in the case of an oblique incident light beam, the amount of surface irregularity is actually larger than approximately <NUM> in an outer peripheral region where there are many oblique incident light beams.

The relationship expressed by Equation <NUM> is established between an incidence angle and exit angle of the diffraction lens surface <NUM> when the lattice pitch is p, the incidence angle of an incident light beam with respect to the envelope surface <NUM> is θ1, the wavelength is λ, the exit angle of Nth-order diffracted light is θ2, the refractive index of an incident space is n1, and the refractive index of an exit space is n2.

As is obvious from Equation <NUM>, the exit angle of zeroth-order light with respect to the envelope surface conforms to the law of refraction (Snell's law), and the exit angles of subsequent orders are determined at substantially equal angle intervals. However, the diffraction lens according to the present example is of a so-called blazed lattice type. Therefore, when an adopted lattice shape has a depth such that the above optical path difference at the frequency of a designed order is obtained at a predetermined incidence angle, energy can be concentrated at a predetermined order.

In order to operate a diffraction plane as a lens in the above instance, the lattice pitch p of the diffraction lens surface is not a fixed value, but needs to be gradually decreased toward an outer periphery. When such a design is to be made, the distribution of optical path difference added by the diffraction plane is usually expressed as a phase function, and the value of its coefficient is optimized by optical design software for determination purposes. When a normalized radius obtained by normalizing the pupil radial coordinates of the lens with an effective radius R is ρ, the phase function φ(ρ) is generally expressed by Equation <NUM>.

In the above instance, α0, α2, and α4 are zeroth-order, second-order, and fourth-order coefficients of the phase function, respectively. These values are used to determine the radial position of a zonal band boundary of the diffraction lens.

<FIG> is a diagram illustrating a method of calculating the radial position of the zonal band boundary. The horizontal axis of a graph in <FIG> represents the normalized radius ρ, and the vertical axis represents the value of the phase function φ(ρ). At each radial position where the phase function value is an integer multiple of 2π, the radial position of its zonal band boundary <NUM> is determined. In this instance, as indicated in Equation <NUM>, the lattice pitch p of the diffraction lens is determined from a condition (Equation <NUM>) in which a phase change determined by multiplying a local slope at a radius ρ where the phase function is positioned is 2Nπ. <MAT><MAT>.

The lattice pitch p in the present example is <NUM> at the outermost periphery in accordance with the designed phase function.

According to design based on wave optics, in a case where high-order diffracted light is used as described above, the wavelength region generated by 40th-order diffracted light at practical diffraction efficiency is very narrow around <NUM>. However, neighboring orders of diffraction arise successively and alternately, that is, the 39th and 41st orders arise on both ends of the 40th order, and then the 38th and 42nd orders arise on both ends of the 39th and 41st orders. The resulting action is substantially equivalent to an action by which high diffraction efficiency is successively achieved in the entire visible light wavelength region. The diffraction angles of the neighboring orders of diffraction are close to the diffraction angle of designed wavelength, and give practically usable light without producing substantially unnecessary stray light.

Meanwhile, in the case of diffraction lens that uses first-order diffracted light described, for example, in Patent Literature <NUM>, the wavelength range within which first-order diffracted light is obtained is wider than in the case of 40th-order diffracted light, but does not cover the entire visible light wavelength region. Therefore, in a wavelength region significantly deviated from the designed wavelength, not only the diffraction efficiency of the first-order diffracted light decreases, but also second-order diffracted light and zeroth-order diffracted light, which have a diffraction angle significantly different from that of first-order diffracted light, arise as unnecessary stray light. This problem is solved by using high-order diffracted light.

The boundary order between high-order diffraction lenses and low-order diffraction lenses varies with the degree of expected advantageous effects. However, conventional diffraction lenses using first-order diffracted light are mostly used within the limits of ± fifth order even in the case of an extended order. Consequently, a diffraction lens of an order greater than ± fifth order can be classified as a high-order diffraction lens that is intended by the present example. Therefore, it is expected that the above-described specific advantageous effects will be provided. Optical systems for use with white light are mostly designed such that the wavelength of green color, such as <NUM>, is adopted as the center wavelength. However, when approximately the fifth order of light diffraction is used at the center wavelength, a plurality of orders generally have a peak exhibiting the maximum diffraction efficiency within the visible light wavelength region. Consequently, using the fifth or higher order of diffraction creates a situation where at least a plurality of orders of diffracted light can be alternately used.

A light beam diffracted by a high-order diffraction lens as described above is actually equivalent to a light beam that is simply refracted by the surface of each zonal band of the diffraction lens surface <NUM>. This lens action is close to the action of a Fresnel lens described, for example, in Patent Literature <NUM> rather than to the action of a diffraction lens when compared with a conventional diffraction lens that uses first-order diffracted light. However, the Fresnel lens is generally formed by dividing the distance of an original lens having a uniform surface from the optical axis into equal intervals in a plane perpendicular to the optical axis or dividing the amount of sag in a plane in the direction of the optical axis into equal intervals, sliding the divided planes in the direction of the optical axis, and arranging the divided planes in a substantially planar manner. Even if the abovementioned surface of each zonal band is optimally shaped for performing a predetermined lens action before sliding, the sliding locally changes the thickness of the lens and deteriorates the performance of the lens.

Meanwhile, the high-order diffraction lens is capable of simultaneously optimizing the shape of the envelope surface, which acts as a base, and the phase function, which defines the lens power given by the diffraction lens, as is the case with a conventional diffraction lens that uses first-order diffracted light. That is to say, lens performance is assured because the shape can be designed so as to obtain a desired lens action in a state where a diffraction lens is prepared.

Although the high-order diffraction lens is described in Patent Literature <NUM>, the high-order diffraction lens according to the present example has the following features.

Lens thickness reduction described above is achievable by applying the high-order diffraction lens according to the present example. Further, the range of the abovementioned ratio of center thickness to focal length is not based on simple design values, but is determined by indirectly defining the condition for delivering the performance of the high-order diffraction lens according to the present example.

Comparisons will now be made to determine whether the lenses described in the aforementioned three patent literatures satisfy the above six features according to the present example.

The results of the above comparisons indicate that the third feature is not satisfied by any of the three patent literatures. The most essential feature of the present example is that the absolute value of the amount of sag in the direction of the optical axis at a lens outer periphery of the envelope surface of the exit diffraction plane is smaller than the maximum absolute value of the amount of sag in the direction of the optical axis at a lens outer periphery of the incident surface.

Advantageous effects of the present example will now be described. When the diffraction lens according to the present example is applied to a vehicular lamp, cut-off line image formation performance during low-beam radiation is sufficiently satisfactory. Before the explanation of the advantageous effects, cut-off line formation will be described.

<FIG> is a diagram illustrating the principles of cut-off line formation during low-beam radiation. Light radiated from an LED light source <NUM> acting as a white light source is reflected from a reflector <NUM> and collected in the vicinity of an edge of a shade <NUM>. This light collection is achievable when the reflector <NUM> is substantially shaped like an ellipsoidal body, the LED light source <NUM> is disposed near one focal point, and the edge of the shade <NUM> is disposed at the other focal point. However, the LED light source <NUM> is not a point light source, but has a certain size. Thus, light generated from a point away from a focal point is radiated toward a position deviated from the edge of the shade <NUM>. In such an instance, a light beam radiated toward the light source from the edge of the shade <NUM> is reflected from the planar portion of the shade <NUM>, and a light beam radiated upward from the edge of the shade <NUM> is not reflected. Both of these light beams are incident on a lens <NUM>. In this instance, when the focal position of the lens <NUM> is disposed to coincide with the edge position of the shade <NUM>, light passing through a portion very close to the edge and reflected light are radiated forward as parallel light beams <NUM> along the optical axis.

At a location several tens of meters forward from the lens <NUM>, which is sufficiently far as compared with a lens aperture, the distribution of radiated light is equal to the distribution of angles of light beams radiated from the lens <NUM>. Therefore, the light beams <NUM> from the vicinity of the edge of the shade <NUM> are radiated onto the cut-off line near the optical axis. Similarly, the edge of the shade <NUM> is continuous in a direction perpendicular to the sheet of <FIG>, and the light beams passing through the vicinity of such a trajectory are both radiated onto a substantially horizontal line along the cut-off line at the location several tens of meters forward from the lens <NUM>. This signifies that the shadow of the edge of the shade <NUM> is uniformly projected onto a location several tens of meters forward. Consequently, an advantageous effect of blocking upward radiating light is provided.

Further, light beams passing through a location above the edge of the shade <NUM> can be regarded as light beams that are both radiated from a location above the focal plane of the lens <NUM>, no matter whether they are reflected from the planar portion of the shade <NUM>. Therefore, such light beams are both radiated forward at a downward angle from the optical axis. These downward light beams <NUM> (indicated by broken lines) irradiate an angular region below the cut-off line. The angular region positioned downward from the shade <NUM> as viewed from the lens <NUM> is the region of a shadow that the light beams from the reflector <NUM> do not reach. Therefore, the region above the cut-off line, which is irradiated when the light beams from the aforementioned region exist, is blocked and darkened. In general, a projector-type low-beam headlight using a lens forms the cut-off line in the above-described manner.

When the cut-off line is set to be formed below the eyes of a driver of an oncoming vehicle passing a host vehicle, the minimum required field of view of the host vehicle can be irradiated without dazzling the driver of the oncoming vehicle. In the case of high-beam radiation, a region above the cut-off line can also be irradiated by removing the shade <NUM> from an optical system.

<FIG> is a diagram illustrating the reference characteristics of light distribution during low-beam radiation. The illustrated reference characteristics are derived when a conventional illumination lens (a non-diffraction lens having a thickness of <NUM> or greater) is used. Contour lines are used to indicate an angular range where relative luminous intensity, that is, the ratio to peak luminous intensity, is <NUM>, <NUM>, or <NUM>. A line portion in which the three contour lines overlap with each other near the horizontal line in the vicinity of a vertical angle of <NUM> degrees is referred to as the cut-off line. As the contour lines overlap with each other, it is evident that the luminous intensity drastically decreases above the cut-off line. An object of the present example is to use a thinned lens in order to achieve light distribution characteristics that clearly form the cut-off line as indicated in <FIG>.

<FIG> is a diagram illustrating the light distribution of a low beam provided by the diffraction lens <NUM> according to the present example. It is found that the contrast of luminous intensity changes of the cut-off line is improved to form a horizontal cut-off line on both the left and right sides. That is to say, it is evident that the luminous intensity drastically decreases above the cut-off line, and that good performance equivalent to the performance of the cut-off line having the reference characteristics indicated in <FIG> is obtained. The cut-off line is bent in the vicinity of a horizontal angle of <NUM> degrees and lowered on the right side in order not to dazzle the driver of the oncoming vehicle coming from the front right of the host vehicle.

<FIG> is a diagram illustrating the light distribution of a high beam provided by the diffraction lens <NUM> according to the present example. The high beam is produced by removing the shade from the low-beam headlight. As the shade is removed, the cut-off line is not formed so that light is radiated upward as well.

The light distribution characteristics of a vehicular lamp are usually evaluated by using a screen positioned <NUM> meters forward. However, the range of evaluation is approximately ±<NUM> degrees in the horizontal direction and approximately ±<NUM> degrees in the vertical direction as indicated in <FIG> so that the horizontal range of evaluation is significantly different from the vertical range of evaluation. Because of such evaluation anisotropy, at least either the incident surface or the exit surface of conventional lenses also adopts a non-rotationally symmetric shape.

The incident surface of the diffraction lens according to the present example is not rotationally symmetric with respect to the optical axis, but is formed of a free-form curved surface. However, the deviation from rotational symmetry (asymmetry) is neither significant nor apparently identifiable. Meanwhile, the diffraction lens surface <NUM> on the exit side in the present example is in a rotationally symmetric shape due to mold processing restrictions. Therefore, it is inevitably required that the incident surface be a non-rotationally symmetric free-form curved surface.

The diffraction lens according to the present example is not only excellent in cut-off line image formation performance during low-beam radiation, but also effective for suppressing a decrease in diffraction efficiency and the generation of diffracted light of unnecessary order. Further, the present example provides a thin lens having a lattice plane that is not significantly deformed during mold processing.

<FIG> is a diagram view illustrating the shape of the diffraction lens according to Example <NUM>. The diagram in <FIG> illustrates, in tabular form, exemplary dimensional specifications for the diffraction lens.

As is the case with Example <NUM>, the diffraction lens <NUM> emits incident light <NUM>, which is incident from a virtual light source <NUM>, as substantially parallel light beams. A high-order diffraction lens surface <NUM> is disposed on an exit surface <NUM> and shaped so as to generate 40th-order diffracted light at a designed center wavelength of <NUM>.

Referring to <FIG>, the following description focuses on comparisons with the first to sixth features mentioned in conjunction with Example <NUM>. First of all, the first and second features are both satisfied because the high-order diffraction lens surface <NUM> is disposed on the exit surface side and a biconvex lens shape is adopted.

As regards the third feature, the magnitude relationship concerning the amount of sag in Example <NUM> is not satisfied. Instead, the magnitude relationship concerning the curvatures of the incident surface and exit surface, which is similar to the third feature, is satisfied. That is to say, the absolute value of the curvature at the surface apex of an envelope surface <NUM> of an exit diffraction plane <NUM> is smaller than the absolute value of the curvature at the surface apex of an incident surface <NUM>. As indicated in <FIG>, the curvature at the surface apex is <NUM> (curvature radius: <NUM>) for the incident surface and -<NUM> (curvature radius: -<NUM>) for the envelope surface of the exit diffraction plane. Thus, the absolute value of the curvature on the exit surface side is smaller than on the incident surface side. Meanwhile, the absolute value of the amount of sag in the direction of the optical axis at a lens outer periphery is <NUM> on the incident surface side and <NUM> on the exit surface side. The absolute value for the exit surface is greater than for the incident surface. As described above, the third feature in Example <NUM> is expressed by the magnitude relationship concerning the curvatures of the incident surface and exit surface.

The fourth to sixth features are all satisfied. More specifically, as regards the fourth feature, the edge thickness is <NUM> while the center thickness is <NUM>. Thus, the ratio of edge thickness to center thickness is <NUM>, which satisfies the range requirements, namely, <NUM> or higher but not higher than <NUM>. As regards the fifth feature, the total lens power is <NUM> D, the secondary coefficient α2 of the phase function of diffraction plane is -<NUM> (rad), and the lens power of diffraction plane is <NUM> D. Thus, the ratio of the diffraction lens power to the total power is <NUM>, which satisfies the range requirements, namely, <NUM> or higher but not higher than <NUM>. As regards the sixth feature, the ratio of center thickness to focal length is <NUM>, which satisfies the range requirements, namely, <NUM> or higher but not higher than <NUM>.

The diffraction lens <NUM> according to the present example also forms a cut-off line that is substantially similar to the one depicted in <FIG>. Further, the image of the cut-off line is properly formed.

<FIG> is a side view illustrating the shape of the diffraction lens according to Example <NUM>. <FIG> illustrates, in tabular form, exemplary dimensional specifications for the diffraction lens.

As is the case with Example <NUM> (<FIG>) and Example <NUM> (<FIG>), the diffraction lens <NUM> emits incident light <NUM>, which is incident from a virtual light source <NUM>, as substantially parallel light beams. A high-order diffraction lens surface <NUM> is disposed on an exit surface <NUM> and shaped so as to generate 40th-order diffracted light at a center wavelength of <NUM>.

The following description focuses on comparisons with the first to sixth features mentioned in conjunction with Example <NUM>. First of all, the first and second features are both satisfied because the high-order diffraction lens surface <NUM> is disposed on the exit surface side and a biconvex lens shape is adopted.

As regards the third feature, the absolute value of the curvature at the surface apex of an envelope surface <NUM> for an exit diffraction plane <NUM> is smaller than the absolute value of the curvature at the surface apex of an incident surface <NUM>, as is the case with Example <NUM>. As indicated in <FIG>, the curvature at the surface apex is <NUM> (curvature radius: <NUM>) for the incident surface and -<NUM> (curvature radius: -<NUM>) for the envelope surface of the exit diffraction plane. Thus, the absolute value of the curvature on the exit surface side is smaller than on the incident surface side. Meanwhile, the absolute value of the amount of sag in the direction of the optical axis at a lens outer periphery is <NUM> on the incident surface side and <NUM> on the exit surface side. The absolute value for the exit surface is slightly greater than for the incident surface so that visually observed difference in the amount of sag is subtle. Consequently, as regards the third feature, Example <NUM> is close to Example <NUM> in terms of a condition concerning the curvature magnitude relationship.

As is obvious from the above results described in conjunction with Examples <NUM> to <NUM>, in order to assure the image formation performance of a vehicular lamp by using a high-order diffraction lens, it is important that the high-order diffraction lens is shaped to establish a predetermined magnitude relationship of the amount of sag or of the curvature between the incident surface and the exit surface. More specifically, it is found that either the absolute value of the amount of sag in the direction of the optical axis at the lens outer periphery of the envelope surface of the exit diffraction plane needs to be smaller than the maximum absolute value of the amount of sag in the direction of the optical axis at the lens outer periphery of the incident surface (the third feature of Example <NUM>) or the absolute value of the curvature at the surface apex of the envelope surface of the exit diffraction plane needs to be smaller than the absolute value of the curvature at the surface apex of the incident surface (the third feature of Examples <NUM> and <NUM>).

<FIG> is a diagram illustrating, for comparison purposes, the light distribution of a diffraction lens noncompliant with a condition (third feature). More specifically, <FIG> illustrates a case where the curvature on the exit surface side of the diffraction lens is greater than the curvature on the incident surface side and the amount of sag on the exit surface side is larger than the amount of sag on the incident surface side. It is evident that the cut-off line is blurred in the vicinity of the optical axis and curved in a region where the horizontal angle is large. This is a phenomenon unique to a case where a diffraction lens is thinned without being formed as a meniscus lens. Anyway, a possible reason is that the third feature mentioned above is not satisfied.

In the above respect, generally known lens characteristics are such that when, for example, the planar side of a plano-convex lens is oriented toward a point light source in a case where the plano-convex lens is used to form an image of the point light source as parallel light at infinity, the blur due to spherical aberration is reduced to exhibit high image formation performance. Thus, it can be expected that higher image formation performance is obtained when the curvature (or the amount of sag) on the exit surface side is greater than the curvature (or the amount of sag) on the incident surface side. However, the third feature of Examples <NUM> to <NUM> is contrary to such expectation. Such a result was not expected by the inventors of the present invention. It provides supporting evidence indicating that the present invention is worth patenting. A theoretical analysis has not been made to conclude that the center thickness can be decreased without sacrificing the image formation performance of a lens when the above condition (third feature) is satisfied. However, it is inferred that a contributing factor is the interrelationship between the overall shape of a lens and the disposition of a high-order diffraction plane.

Example <NUM> will now be described with reference to a vehicular lamp that uses the diffraction lens described in conjunction with Examples <NUM> to <NUM>.

<FIG> is a diagram illustrating a configuration of a vehicular lamp according to Example <NUM>.

In the vehicular lighting deice, light radiated, for example, from an LED light source <NUM> acting as a white light source is reflected from an inner specular surface of a concave reflector <NUM>, and collected by the concave reflector <NUM>. A cover called a shade <NUM> is disposed in the vicinity of such a light collection position. The shade <NUM> is designed to reflect the light distribution (low beam) for distant radiation. The light transmitted through the shade <NUM> is radiated forward by a diffraction lens <NUM>. The diffraction lens <NUM> has the same characteristics as the diffraction lenses <NUM>, <NUM>, <NUM> described in conjunction with Examples <NUM> to <NUM>. When the shade <NUM> is curved so as to match the field curvature of the lens, the bright-dark boundary (cut-off line) of light distribution for radiation can be made sharper. High-beam radiation can be achieved by making the shade <NUM> movable and removing it from the optical path.

Claim 1:
A vehicular lamp (<NUM>) comprising:
a light source (<NUM>) that radiates light;
a reflector (<NUM>) that reflects and collects the light radiated from the light source;
a shade (<NUM>) that blocks part of the light reflected and collected by the reflector; and
a diffraction lens (<NUM>, <NUM>, <NUM>, <NUM>) that receives incident light transmitted through the shade and radiates the incident light forward of a vehicle;
wherein the diffraction lens has an incident side (<NUM>, <NUM>, <NUM>) and an exit side (<NUM>, <NUM>, <NUM>) that are both convexly shaped, includes an exit diffraction plane (<NUM>, <NUM>, <NUM>) that has an absolute value for the order of diffraction of <NUM> or greater and is disposed on the exit side, and is adapted such that the absolute value of a curvature at the surface apex of an envelope surface (<NUM>, <NUM>, <NUM>) of the exit diffraction plane is smaller than the absolute value of a curvature at the surface apex of an incident surface, or the absolute value of the amount of sag in the direction of the optical axis at an outer periphery of the envelope surface of the exit diffraction plane is smaller than the maximum absolute value of the amount of sag in the direction of the optical axis at an outer periphery of the incident surface;
wherein the ratio of an interval between the incident surface at a radial position farthest from the optical axis (<NUM>, <NUM>, <NUM>) in a lens effective region and the envelope surface of the exit diffraction plane at a radial position farthest from the optical axis in a lens effective region to the interval between the surface apex of the incident surface and the surface apex of the envelope surface of the exit diffraction plane is <NUM> or higher but not higher than <NUM>;
wherein the order of diffraction of the exit diffraction plane is defined as (n-<NUM>)d/λ, wherein λ is a designed center wavelength, n is a refractive index of the diffraction lens, and d is a surface irregularity; and
wherein the lens effective region is an actual range of light passing through the diffraction lens.