The present invention generally relates to layered embroidered headwear and methods for producing layered embroidered headwear. More particularly, the embroidering method of the present invention can produce headwear, including cap panels for producing the headwear, that comprises vivid decorations and designs, which are highly breathable and lightweight. As described herein, the embroidering method of the present invention can apply multiple levels of embroidering thread on top of each other to produce elaborate patterns or designs on the headwear without jeopardizing the breathability or weight of the headwear.

The present invention generally relates to layered embroidered headwear and methods for producing layered embroidered headwear. More particularly, the embroidering method of the present invention can produce headwear, including cap panels for producing the headwear, that comprises vivid decorations and designs, which are highly breathable and lightweight. As described herein, the embroidering method of the present invention can apply multiple levels of embroidering thread on top of each other to produce elaborate patterns or designs on the headwear without jeopardizing the breathability or weight of the headwear.

Tools are provided that communicate to a pattern designer how much yarn is being used on every needle for a given tuft height pattern and permit the designer to adjust the pattern accordingly to balance the yarn usage on the needles. An electronic representation of a pattern design is received for controlling a carpet tufting operation. The pattern design includes a pile height per tuft. A grid is provided for representing the pattern design using different visual cues to represent different pile heights. A graph depicting use-of-yarn per needle for the carpet tufting operation is generated. The grid and the graph can be on a common user interface and can be viewable at the same time on a display device.

Tools are provided that communicate to a pattern designer how much yarn is being used on every needle for a given tuft height pattern and permit the designer to adjust the pattern accordingly to balance the yarn usage on the needles. An electronic representation of a pattern design is received for controlling a carpet tufting operation. The pattern design includes a pile height per tuft. A grid is provided for representing the pattern design using different visual cues to represent different pile heights. A graph depicting use-of-yarn per needle for the carpet tufting operation is generated. The grid and the graph can be on a common user interface and can be viewable at the same time on a display device.

Tools are provided that communicate to a pattern designer how much yarn is being used on every needle for a given tuft height pattern and permit the designer to adjust the pattern accordingly to balance the yarn usage on the needles. An electronic representation of a pattern design is received for controlling a carpet tufting operation. The pattern design includes a pile height per tuft. A grid is provided for representing the pattern design using different visual cues to represent different pile heights. A graph depicting use-of-yarn per needle for the carpet tufting operation is generated. The grid and the graph can be on a common user interface and can be viewable at the same time on a display device.

Tools are provided that communicate to a pattern designer how much yarn is being used on every needle for a given tuft height pattern and permit the designer to adjust the pattern accordingly to balance the yarn usage on the needles. An electronic representation of a pattern design is received for controlling a carpet tufting operation. The pattern design includes a pile height per tuft. A grid is provided for representing the pattern design using different visual cues to represent different pile heights. A graph depicting use-of-yarn per needle for the carpet tufting operation is generated. The grid and the graph can be on a common user interface and can be viewable at the same time on a display device.

Tools are provided that communicate to a pattern designer how much yarn is being used on every needle for a given tuft height pattern and permit the designer to adjust the pattern accordingly to balance the yarn usage on the needles. An electronic representation of a pattern design is received for controlling a carpet tufting operation. The pattern design includes a pile height per tuft. A grid is provided for representing the pattern design using different visual cues to represent different pile heights. A graph depicting use-of-yarn per needle for the carpet tufting operation is generated. The grid and the graph are on a common user interface and are viewable at the same time on a display device.

Tools are provided that communicate to a pattern designer how much yarn is being used on every needle for a given tuft height pattern and permit the designer to adjust the pattern accordingly to balance the yarn usage on the needles. An electronic representation of a pattern design is received for controlling a carpet tufting operation. The pattern design includes a pile height per tuft. A grid is provided for representing the pattern design using different visual cues to represent different pile heights. A graph depicting use-of-yarn per needle for the carpet tufting operation is generated. The grid and the graph are on a common user interface and are viewable at the same time on a display device.

A method of dynamically changing stitch density of a quilting pattern during sewing is provided. Embodiments of the invention include dynamically changing stitch density along an axis of a sewing pattern based on identifying sewing pattern elements, which may include line segments and arc segments. Each of the line segments and/or arc segments is assigned a dynamically adjusted stitch density based on analysis of each pattern element and/or adjacent element. An adjusted stitch density is assigned to portions of pattern elements that satisfy a threshold measurement for sewing with an adjusted stitch density. In embodiments, a standard stitch density, intermediate stitch density, or an altered stitch density is automatically assigned to each portion of a sewing pattern based on an analysis of threshold length of an element, a threshold angle of a portion of the element with respect to the axis, and/or the stitch density assigned to an adjacent element.

A sewing machine includes an embroidery frame moving portion, a sewing portion, a processor, and a memory. The memory is configured to store computer-readable instructions that, when executed by the processor, cause the processor to perform the steps of acquiring image data created by a device and obtained by capturing an image of a range that includes at least one reference mark and at least one indicator mark, computing positioning data based on the image data, specifying an embroidery pattern to be formed in a sewing workpiece clamped in an embroidery frame, setting at least one of a position and an angle of the embroidery pattern on the sewing workpiece, based on the positioning data, acquiring embroidery data, causing the embroidery frame moving portion and the sewing portion to form the stitches that make up the embroidery pattern in the sewing workpiece, based on the embroidery data.