JP7843941B2 - LED filament - Google Patents

Description

This invention relates to a light-emitting diode (LED) filament. This invention also relates to a lamp or lighting fixture having such an LED filament. This invention also relates to a lighting system having such a lamp or lighting fixture.

The lighting trend is LED filament lamps. LED filament lamps are designed to resemble traditional incandescent light bulbs, featuring a visible filament for aesthetic and light distribution purposes, but utilizing highly efficient light-emitting diodes.

The objective of this invention is to improve the performance and/or function of LED filaments.

According to a first aspect of the present invention, this and other objectives are achieved by an LED filament comprising: a light-emitting diode (LED) filament; a carrier; a plurality of first blue LEDs adapted to emit first blue light, disposed on the carrier; and a first elongated encapsulant covering the plurality of first blue LEDs and at least a portion of the carrier, the first elongated encapsulant having a first luminescent material configured to convert at least a portion of the first blue light into first converted light; an LED filament having the first elongated encapsulant having an upper surface; a string of second blue LEDs adapted to emit second blue light; and a string of second blue LEDs disposed on the upper surface of the LED filament, wherein the light output surface of the second blue LEDs faces away from the LED filament.

In this method, optical crosstalk (i.e., the action of the operating blue LED stimulating the phosphor converter of the LED filament, which then emits light of a different color) is reduced or eliminated, and therefore, pure blue light can be supplied.

Preferably, less than 5% of the light from the second blue LED is converted (by the first luminescent material), more preferably less than 3% of the light from the second blue LED is converted (by the first luminescent material), and most preferably less than 1%, for example 0%, of the light from the second blue LED is converted (by the first luminescent material).

The upper surface has a top surface area (TSA), and the string of the second blue LEDs has a string area (SA), where SA < 0.4 TSA, and specifically SA < 0.2 TSA. In this configuration, the string of the second blue LEDs does not block and/or absorb (excessive amounts of) the first blue light and/or the first converted light.

The LED filament may further include a controller configured to individually control the emission of the first blue light from the plurality of first blue LEDs and the emission of the second blue light from the string of second blue LEDs. In this configuration, the LED filament can selectively supply white light, colored light, or a combination thereof.

The string of the second blue LEDs is arranged on or off a light-transmitting substrate. This allows the first blue light and/or the first converted light to easily pass through the string of the second blue LEDs, which is arranged above the first blue LEDs. While the second blue LEDs and their electrical tracks may still block some light, the first blue light and/or converted light passes through the light-transmitting substrate or very close to the second blue LEDs and their electrical tracks.

The string of the second blue LED may be covered with a second elongated encapsulant that does not contain luminescent material or light-scattering material. In other words, the second elongated encapsulant contains no luminescent material or light-scattering material whatsoever. In this configuration, the optical light distribution requirements of the LED filament can be satisfied. The second elongated encapsulant may, for example, be dome-shaped.

The string of the second blue LEDs may have an LED pitch of less than 1000 μm, preferably less than 800 μm, more preferably less than 600 μm, and most preferably less than 500 μm. The "LED pitch" may be the distance between the centers of adjacent second blue LEDs in the string.

The LED filament may further have a plurality of red LEDs adapted to emit red light, and optionally a plurality of green LEDs adapted to emit green light, wherein the plurality of red LEDs and the optional plurality of green LEDs are arranged on the upper surface of the LED filament. Alternatively, the plurality of red LEDs and the optional plurality of green LEDs may be arranged on the support of the LED filament, for example, under or next to the first elongated encapsulant. The plurality of red LEDs and the optional plurality of green LEDs enable the LED filament to supply light of various colors. Accordingly, the controller may further be configured to individually control the emission of red light from the plurality of red LEDs and the emission of green light from any plurality of green LEDs.

The plurality of red LEDs and the optional plurality of green LEDs may be arranged in at least one string, such as a string of red LEDs and another string of green LEDs, or a string of second blue LEDs, red LEDs, and optional green LEDs. Therefore, in one or more embodiments, the string of second blue LEDs includes only second blue LEDs. Also, in one or more embodiments, the string of second blue LEDs includes the plurality of red LEDs and the optional plurality of green LEDs.

The first luminescent material may be configured to convert at least a portion of the first blue light, together with the first blue light emitted by the plurality of first blue LEDs that was not converted, into a first converted light including first green/yellow light and first red light that forms a first white light having a first correlated color temperature (CCT1). Preferably, CCT1 ≤ 2500K.

The filament circuit further comprises a plurality of third blue LEDs adapted to emit third blue light, disposed on the support, and a third elongated encapsulant covering the plurality of third blue LEDs and at least a portion of the support, the third elongated encapsulant having a second luminescent material configured to convert at least a portion of the third blue light into second converted light. In this configuration, the LED filament can still supply white light with various color temperatures while reducing or avoiding optical crosstalk.

The string of the second blue LED may be arranged at the boundary between the first elongated encapsulant and the third elongated encapsulant in order to reduce or minimize its influence on the first blue/converted light and the third blue/second converted light.

The second luminescent material may be configured to convert at least a portion of the third blue light, together with the third blue light emitted by the plurality of third blue LEDs that was not converted, into a second converted light including second green/yellow light and second red light, which forms a second white light having a second correlated color temperature (CCT2) higher than the first correlated color temperature. Preferably, CCT2 - CCT1 ≥ 500K, and more preferably, CCT2 - CCT1 ≥ 1000K. Generally, CCT2 ≥ 3500K. Furthermore, the color rendering index (CRI) of the first white light and the second white light may be at least 80.

According to a second aspect of the present invention, a lamp or lighting fixture is provided having an LED filament according to the first aspect and an antenna functionally coupled to the controller of the LED filament. The antenna enables remote control of the lamp or lighting fixture. The lamp may be, for example, a (retrofit) light bulb.

According to a third aspect of the present invention, a lighting system is provided comprising a lamp or lighting fixture according to the second aspect, and at least one (remote) user interface for supplying user input and/or at least one (remote) sensor for detecting data, wherein the controller is configured to control the plurality of first blue LEDs and the plurality of second blue LEDs based on the user input and/or the data, and to optionally control the plurality of red LEDs, the plurality of green LEDs and the plurality of third blue LEDs.

It should be noted that this invention relates to all possible combinations of the features listed in the claims.

Herein, these and other embodiments of the present invention will be described in more detail with reference to the accompanying drawings illustrating embodiments of the present invention.
This is a cross-sectional view of an LED filament according to an embodiment of the present invention. Figure 1a is a side view of the LED filament. Figure 1a is a top view of the LED filament. An LED filament according to another embodiment of the present invention is shown. An LED filament according to another embodiment of the present invention is shown. An LED filament according to another embodiment of the present invention is shown. An LED filament according to another embodiment of the present invention is shown. An LED filament according to another embodiment of the present invention is shown. This is a side view of an embodiment of the present invention including a lamp.

The sizes of layers and regions as illustrated in the figures may be exaggerated for illustrative purposes and are therefore shown to illustrate the general structure of embodiments of the present invention. Throughout, similar reference numerals refer to similar elements.

The present invention will now be described in more detail with reference to the accompanying drawings illustrating currently preferred embodiments. However, the present invention can be carried out in a variety of forms and should not be construed as being limited to the embodiments described herein; more precisely, these embodiments are shown for completeness and perfection and fully convey the scope of the invention to those skilled in the art.

Figures 1a to 1c illustrate an LED filament 10 according to an embodiment of the present invention. The LED filament 10 can supply LED filament (device) light 12.

The LED filament 10 has an LED filament 14. The LED filament 14 may be rigid or flexible.

The LED filament 14 has a support 16. The support 16 is generally a substrate. The support 16 is generally elongated. Preferably, the LED filament 14 has a length L, where L > 5D. The distance D corresponding to the width of the support 16 may be, for example, in the range of 0.5 to 5 mm. The support 16 may include two elongated edges 18a and 18b arranged at a distance D from each other, a first (main) surface 20a, and a second (main) surface 20b arranged on the opposite side of the first surface 20a. The support 16 may be rigid (e.g., made from polymer, glass, quartz, metal, or sapphire) or flexible (e.g., made from polymer or metal, such as film or foil).

The LED filament 14 further comprises a plurality of first blue LEDs 22 adapted to emit first blue light 24. The first blue light 24 may have a main peak wavelength within, for example, a wavelength range of 450 to 490 nm. The plurality of first blue LEDs 22 are arranged on a support 16. Specifically, the plurality of first blue LEDs 22 may be mounted on a first surface 20a of the support 16. Furthermore, the plurality of first blue LEDs 22 are preferably arranged in a linear array/string/single row along the longitudinal centerline of the support 16. The number of first blue LEDs 22 may be, for example, at least 10 or at least 20.

The LED filament 14 further comprises a plurality of first blue LEDs 22 and a first elongated encapsulant 26 covering at least a portion of the support 16. The first elongated encapsulant 26 has a first luminescence material 28 configured to convert at least a portion of the first blue light 24 into a first converted light 30. Specifically, the first luminescence material 28 may be configured to convert at least a portion of the first blue light 24, together with the unconverted first blue light 24, into a first converted light 30 including first green/yellow light and first red light that form a first white light 32 having a first correlated color temperature CCT 1. Preferably, CCT 1 ≤ 2500K (warm white light). Furthermore, the color rendering index (CRI) of the first white light 32 is preferably at least 80. The first luminescence material 28 may be a phosphor, and the first elongated encapsulant 26 may be made of, for example, silicone. Multiple first blue LEDs 22, each comprising a first elongated encapsulant 26 and a first luminescent material 28, may be referred to as a first white light source.

The LED filament 14 further has an upper surface 34, which in this case is the upper surface 34 of the first elongated encapsulant 26. The upper surface 34 is on the opposite side of the bottom surface (second (support) surface 20b) of the LED filament 14. The upper surface 34 and the bottom surface 20b may be enclosed by end faces. As seen in Figure 1c, the upper surface 34 has an upper surface area TSA, and generally, TSA = L × D.

The LED filament 10 further includes a second light source, which includes a string 36 of second blue LEDs 38 adapted to emit second blue light 40. The string 36 of second blue LEDs 38 here includes only second blue LEDs 38. The string of second blue LEDs is disposed either directly on the top surface 34 of the LED filament 14, or on a light-transmitting substrate (not shown) above the top surface 34 of the LED filament 14, such that the light output surfaces 42 of the second blue LEDs 38 face away from the LED filament 14. That is, during operation, the second blue light 40 is emitted away from the first encapsulant 26 containing the luminescent material 28. Each light output surface 42 may be the top surface of the blue LED 38, while the bottom surface 44 opposite the blue LED 38 faces the top surface 34 of the LED filament 14 (of the first elongated encapsulant 26) and may be mounted therein. Therefore, the second blue LED 38 is sometimes referred to as a top-emitting type second blue LED 38. The string 36 of the second blue LED 38 is preferably arranged at the longitudinal centerline of the upper surface 34 of the LED filament 14, as seen in Figure 1c. That is, the first and second blue LEDs 22 and 42 can be arranged stacked and facing the same direction. The number of second blue LEDs 38 may be, for example, at least 10 or at least 20.

By having a string 36 of second blue LEDs 38 positioned above/in front of the first elongated encapsulant 26/first luminescent material 28, and emitting second blue LED light 40 away from the first elongated encapsulant 26/first luminescent material 28 during operation, optical crosstalk (i.e., the action of the operating blue LED 38 stimulating the phosphor converter/luminescent material 28 of the LED filament, which then causes the phosphor converter/luminescent material 28 to emit light of a different color) is reduced/eliminated, and therefore, pure blue light can be supplied.

The string 36 of the second blue LED 38 may have a string area SA. The string area SA may be the sum of the area of the light output surface 42 of the second blue LED 38 and the area of the associated electrical track. The (approximate) string area SA is shown by diagonal stripes in Figure 1c. Preferably, SA < 0.2 TSA, thereby preventing the second blue LED 38 from blocking an excessive amount of the first blue light 24 and/or the first converted light 30. The electrical track may include, for example, copper wire/track. Furthermore, the string 36 of the second blue LED 38 may have an ultra-narrow pitch LED pitch P of less than 1000 μm.

The LED filament 10 may further include a second elongated encapsulant 46 that covers the string 36 of the second blue LED 38. The second elongated encapsulant 46 does not contain luminescent material or light scattering material. The second elongated encapsulant 46 may be, for example, transparent. The second elongated encapsulant 46 may be made of, for example, silicone. The second elongated encapsulant 46 may have a dome-shaped cross-section with respect to its width D, as seen, for example, in Figure 1a. The dome-shaped cross-section may be uniform over substantially the entire length of the second elongated encapsulant 46.

The LED filament 10 may further include an electronic controller 48. The controller 48 is configured to individually control the emission of first blue light 24 from a plurality of first blue LEDs 22 and the emission of second blue light 40 from a string of second blue LEDs 38. Therefore, during operation, the LED filament 10 in Figures 1a to 1c can selectively supply white light 32, blue light 40, or a combination thereof.

Figure 2a is a cross-sectional view of an LED filament 10 according to another embodiment. The LED filament 10 in Figure 2a is similar to the LED filament 10 in Figures 1a to 1c, but further comprises a plurality of red LEDs 50 adapted to emit red light 52 and a plurality of green LEDs 54 adapted to emit green light 56. The plurality of red LEDs 50 and the plurality of green LEDs 54 are arranged either directly on the upper surface 34 of the LED filament 14 or on a light-transmitting substrate (not shown) on the upper surface 34 of the LED filament 14, such that their light output surfaces 42' face away from the LED filament 14. The plurality of red LEDs 50 are arranged in a string on one side of the string 36 of the second blue LEDs 38, and the string of red LEDs 50 is parallel to the string 36 of the second blue LEDs 38. Multiple green LEDs 54 are arranged in a separate string on the other side of the string 36 of the second blue LEDs 38, and the string of green LEDs 54 is also parallel to the string 36 of the second blue LEDs 38. The number of red LEDs 50 may be, for example, at least 10 or at least 20. The number of green LEDs 54 may be, for example, at least 10 or at least 20. Multiple red LEDs 50 may be covered by an elongated encapsulant 58 similar to the second elongated encapsulant 46. Similarly, multiple green LEDs 54 may be covered by an elongated encapsulant 60 similar to the second elongated encapsulant 46. Alternatively, the second elongated encapsulant 46 may be extended to also cover the red LEDs 50 and green LEDs 54 (not shown in Figure 2a). The controller 48 may here be configured to individually control the emission of red light 52 from the multiple red LEDs 50 and the emission of green light 56 from any multiple green LEDs 54. Therefore, during operation, the LED filament 10 in Figure 2a can selectively supply white light 32, blue light 40, red light 50, green light 54, or a combination thereof.

Figures 2b to 2c are cross-sectional views of the LED filament 10 according to other embodiments. The LED filament 10 in each of Figures 2b to 2c is similar to the LED filament 10 in Figure 2a, except that a plurality of red LEDs 50 and a plurality of green LEDs 54 are arranged on the support 16 of the LED filament 14. Specifically, the plurality of red LEDs 50 may be arranged and mounted on the first surface 20a of the support 16 (on one side of the plurality of first blue LEDs 22), and the plurality of green LEDs 54 may similarly be arranged and mounted on the first surface 20a of the support 16 (on the opposite side of the plurality of first blue LEDs 22). That is, the plurality of red LEDs 50 may be arranged in a string parallel to the linear array/string/single row of the first blue LEDs 22. Similarly, the plurality of green LEDs 54 may be arranged in another string parallel to the linear array/string/single row of the first blue LEDs 22.

In Figure 2b, the first elongated encapsulant 26 covers not only the multiple first blue LEDs 22, but also the multiple red LEDs 50, the multiple green LEDs 54, and at least a portion of the support 16. In Figure 2c, the first elongated encapsulant, represented by reference numeral 26', has an extended portion limited in the width direction, covering the multiple first blue LEDs 22 and only a portion of the support 16, while not covering the multiple red LEDs 50 and the multiple green LEDs 54. The multiple red LEDs 50 and the multiple green LEDs 54 may not be covered, or they may be provided with elongated encapsulants 58, 60 similar to those in Figure 2a (not shown in Figure 2c).

Figure 2d is a top view of the LED filament 10 according to another embodiment. The LED filament 10 in Figure 2d is similar to the LED filament 10 in Figure 2a, except that the string comprising the second blue LED 38 also includes a plurality of red LEDs 50 and a plurality of green LEDs 54. That is, the plurality of second blue LEDs 38, the plurality of red LEDs 50 and the plurality of green LEDs 54 are arranged in a single string/linear/row 36', preferably at the longitudinal centerline of the top surface 34 of the LED filament 14. The LEDs 38, 50, and 54 can be arranged in the string 36' in an alternating color order (e.g., R-G-B-R-G-B, i.e., (RGB)n, where n is preferably ≥ 5), but other arrangements such as batching are also possible. Here, the second elongated encapsulant 46 may also cover the red LEDs 50 and green LEDs 54.

Figure 2e is a cross-sectional view of an LED filament 10 according to another embodiment. The LED filament 10 in Figure 2e is similar to the LED filament 10 in Figure 2a, except that the LED filament 14 further comprises a plurality of blue LEDs 62 adapted to emit a third blue light. The plurality of third blue LEDs 62 are arranged on a support 16. Specifically, the plurality of third blue LEDs 62 may be mounted on the first surface 20a of the support 16. Furthermore, the plurality of third blue LEDs 62 are preferably arranged in a linear array/string/single row. The string of third blue LEDs 62 may be arranged parallel to the aforementioned string of first blue LEDs 22. These strings may be mounted on both sides of the longitudinal centerline of the support 16, as shown in Figure 2e. The number of third blue LEDs 62 may be, for example, at least 10 or at least 20.

The LED filament 14 in Figure 2e further comprises a plurality of third blue LEDs and a third elongated encapsulant 66 covering a portion of the support 16. The third elongated encapsulant 66 has a second luminescence material 68 configured to convert at least a portion of the third blue light 64 into a second converted light 70. Specifically, the second luminescence material 68 may be configured to convert at least a portion of the third blue light 64, together with the unconverted third blue light 64, into a second converted light 70 including second green/yellow light and second red light that forms a second white light 72 having a second correlated color temperature CCT2 different from the first correlated color temperature CCT1. Preferably, CCT2-CCT1 ≥ 500K, and more preferably, CCT2-CCT1 ≥ 1000K. Generally, CCT2 ≥ 3500K. Furthermore, the color rendering index (CRI) of the second white light 72 is preferably at least 80. The second luminescent material 68 may be a phosphor, and the second elongated encapsulant 66 may be made of, for example, silicone. Multiple third blue LEDs 62, each comprising a third elongated encapsulant 66 and a second luminescent material 68, may be referred to as a third white light source.

Each of the first elongated encapsulant 26 and the third elongated encapsulant 66 can cover approximately half of the support 16 when viewed from the width direction. Therefore, the first elongated encapsulant 26 and the third elongated encapsulant 66 can be parallel to each other (in the longitudinal direction of the LED filament 12/LED filament 14). The upper surface 34 of the LED filament 14 can be formed here by the upper surfaces of the first elongated encapsulant 26 and the third elongated encapsulant 66. Furthermore, a string of second blue LEDs 38 can be arranged at the boundary 74 between the first elongated encapsulant 26 and the third elongated encapsulant 66 (on the upper surface 34). Multiple red LEDs 50 may be arranged on the first elongated encapsulant 26, and multiple green LEDs 54 may be arranged on the third elongated encapsulant 66. Alternatively, a single string of a second blue LED 38, a red LED 50, and a green LED 54 (as shown in Figure 2d) may be arranged at the boundary 74 (not shown).

The controller 48 may also be configured to individually control the emission of third blue light 64 from multiple third blue LEDs 62. Therefore, during operation, the LED filament 10 in Figure 2e can selectively supply first white light 32, second white light 72, blue light 40, red light 50, green light 54, or a combination thereof. Furthermore, the second elongated encapsulant may be a common elongated encapsulant 46' that covers not only the string 36 of the second blue LEDs 38, but also multiple red LEDs 50 and any multiple green LEDs 54. The common elongated encapsulant 46' may simplify the manufacturing of the LED filament 10. Alternatively, the LED filament 10 in Figure 2e may have individual elongated encapsulants 46, 58, 60, for example, as shown in Figure 2a.

Figure 4 illustrates a lamp 102 according to an embodiment of the present invention. The lamp 102 comprises at least one LED filament 10, a controller 48, and an antenna 104 functionally coupled to the controller 48. The antenna 104 may be configured to receive user input from at least one user interface 106 and/or data from at least one sensor 108. The controller 54 may also be configured to control a plurality of first blue LEDs 22 and a plurality of second blue LEDs 38, as well as optional red LEDs 50, green LEDs 54, and third blue LEDs 62, based on user input from the user interface 106 and/or (detection) data from at least one sensor 108. The lamp 102, and the user interface 106 and/or sensor 108, may be referred to as a lighting system 100. The user interface 106 and/or sensor 108 may be located far from the lamp 102. The user interface 106 may be embodied, for example, in a mobile phone. At least one sensor 108 may include, for example, at least one of a camera, a light sensor, a presence sensor, and a proximity sensor.

The LED filaments 14/10 are arranged in a coiled configuration here, but other configurations such as a linear configuration are also possible. The lamp 102 may further include an envelope 110 surrounding the LED filaments 14/10, and a base or socket 112 for electrically and mechanically connecting the lamp 102 to an external socket (not shown). The lamp 102 may be, for example, a retrofit light bulb.

Those skilled in the art will understand that the present invention is by no means limited to the preferred embodiments described above. Conversely, many modifications and changes are possible within the scope of the appended claims.

Furthermore, those skilled in the art will be able to understand and achieve variations to the disclosed embodiments in the implementation of the claimed invention by studying the drawings, specification, and appended claims. In the claims, the word “has” does not exclude other elements or steps, and singular nouns do not exclude plurals. The mere fact that certain means are listed in different dependent claims does not imply that combinations of these means cannot be used advantageously.

Claims (15)

It is an LED filament,
support,
A plurality of first blue LEDs adapted to emit first blue light, wherein the plurality of first blue LEDs are arranged on the support,
A first elongated encapsulant covering the plurality of first blue LEDs and at least a portion of the support, the first elongated encapsulant having a first luminescent material configured to convert at least a portion of the first blue light into first converted light, the first elongated encapsulant having an upper surface, and a string of second blue LEDs adapted to emit second blue light, the string of second blue LEDs being directly attached to the upper surface of the first elongated encapsulant, the light output surface of the second blue LEDs facing away from the upper surface, the string having an LED filament. The LED filament according to claim 1, wherein the upper surface has an upper surface area TSA, and the string of the second blue LED has a string area SA, with SA < 0.4 TSA. The LED filament according to claim 1 or 2, further comprising a controller configured to individually control the emission of the first blue light from the plurality of first blue LEDs and the emission of the second blue light from the string of second blue LEDs. The LED filament according to claim 1 or 2, wherein the string of the second blue LED is disposed on a light -transmitting substrate directly on the upper surface of the first elongated encapsulant, or on the upper surface of the first elongated encapsulant. The LED filament according to claim 1 or 2, wherein the string of the second blue LED is covered with a second elongated encapsulant that does not contain a luminescent material and a light scattering material. The LED filament according to claim 1 or 2, wherein the string of the second blue LED has an LED pitch of less than 1000 μm. The LED filament according to claim 1 or 2, further comprising a plurality of red LEDs adapted to emit red light, optionally further comprising a plurality of green LEDs adapted to emit green light, wherein the plurality of red LEDs and the optional plurality of green LEDs are arranged on the upper surface of the first elongated sealing material. The LED filament according to claim 7, wherein the plurality of red LEDs and the optional plurality of green LEDs are arranged in at least one string of the LED filament. The LED filament according to claim 7, wherein the string of the second blue LEDs includes only the second blue LED. The LED filament according to claim 7, wherein the string of the second blue LEDs also includes the plurality of red LEDs and an optional plurality of green LEDs. The LED filament according to claim 1 or 2, wherein the first luminescent material is configured to convert at least a portion of the first blue light, together with the first blue light emitted by the plurality of first blue LEDs that was not converted, into a first converted light including first green/yellow light and first red light that forms a first white light having a first correlated color temperature CCT1, and CCT1 ≤ 2500K. The aforementioned LED filament
The LED filament according to claim 1 or 2, comprising a plurality of third blue LEDs adapted to emit third blue light, the plurality of third blue LEDs disposed on the support, and a third elongated encapsulant covering the plurality of third blue LEDs and at least a portion of the support, the third elongated encapsulant having a second luminescent material configured to convert at least a portion of the third blue light into second converted light. The LED filament according to claim 12, wherein the string of the second blue LED is arranged at the boundary between the first elongated encapsulant and the third elongated encapsulant. The LED filament according to claim 12, wherein the second luminescent material is configured to convert at least a portion of the third blue light, together with the third blue light emitted by the plurality of third blue LEDs that was not converted, into a second converted light including a second green/yellow light and a second red light that forms a second white light having a second correlated color temperature CCT2 higher than the first correlated color temperature, wherein CCT2 - CCT1 ≥ 500K, and the color rendering index of the first white light and the second white light is at least 80. A lamp or lighting fixture including an LED filament according to claim 1 or 2, and an antenna functionally coupled to the controller of the LED filament,
A lighting system having at least one user interface for supplying user input and/or at least one sensor for detecting data,
A lighting system in which the controller is configured to control the plurality of first blue LEDs and the second blue LEDs based on the user input and/or the data.