A control information generating method includes generating thermal transfer control information based on an amount of ink to be used for printing of a printing medium, in a case where thermal transfer control information for heating a printing medium printed on a first medium based on image data and thermally transferring the printing medium to a second medium is generated.

A thermal printhead includes a substrate, a protrusion formed on an obverse surface of the substrate and extending in a main scanning direction, a heat storage layer formed on a top surface of the protrusion, and a plurality of heat-generating parts arranged along the main scanning direction on the heat storage layer. The substrate and the protrusion are integrally formed from a single-crystal semiconductor.

A thermal head of the present disclosure includes a substrate 7, a heat generating unit 9, an electrode, a covering layer 27, and a covering member 29. The heat generating unit 9 is positioned above the substrate 7. The electrode is positioned above the substrate and connected to the heat generating unit 9. The covering layer 27 covers at least a part of the electrode when viewed in plan. The covering member 29 is positioned on the covering layer 27. The covering layer 27 has an upper surface 27a and a lateral surface 27b that is positioned on a side of the heat generating unit 9. An arithmetic-average surface roughness Ra of the lateral surface 27b is higher than an arithmetic-average surface roughness Ra of the upper surface 27a.

A thermal head includes: an underglaze layer provided on an insulating substrate; an electrode provided on the underglaze layer; a heat generator provided on the electrode; a first protective layer containing a glass material and covering at least the heat generator; and a second protective layer provided on the first protective layer, having a melting point higher than that of the first protective layer, and made of a material whose thermal expansion coefficient at a temperature of 1000 C. or lower is substantially constant.

A thermal printhead includes a substrate, a protrusion formed on an obverse surface of the substrate and extending in a main scanning direction, a heat storage layer formed on a top surface of the protrusion, and a plurality of heat-generating parts arranged along the main scanning direction on the heat storage layer. The substrate and the protrusion are integrally formed from a single-crystal semiconductor.

A heater includes: a substrate including a first surface and a second surface located opposite to the first surface relative to the substrate; a first heating pattern disposed on a first-surface side of the substrate; a second heating pattern disposed on the first-surface side of the substrate and located at a position different from a position of the first heating pattern; a first terminal to which electricity is to be supplied; a first power-supply pattern electrically connecting the first terminal and the first heating pattern to each other and disposed on a second-surface side of the substrate; and a first electrically-continuous portion extending through the substrate and electrically connecting the first power-supply pattern and the first heating pattern to each other.

An asymmetric thermal print head includes a print head body and a plurality of print elements supported on the print head body. The print elements are aligned along a first axis. Each print element includes a heater portion having a burn width measured along the first axis corresponding to a first print resolution, and a burn length measured along a second axis, which is perpendicular to the first axis, corresponding to a second print resolution. The second print resolution is higher than the first print resolution. One or more control circuits are configured to individually activate the print elements.

A thermal head of the present disclosure includes a substrate 7, a heat generating unit 9, an electrode, a covering layer 27, and a covering member 29. The heat generating unit 9 is positioned above the substrate 7. The electrode is positioned above the substrate and connected to the heat generating unit 9. The covering layer 27 covers at least a part of the electrode when viewed in plan. The covering member 29 is positioned on the covering layer 27. The covering layer 27 has an upper surface 27a and a lateral surface 27b that is positioned on a side of the heat generating unit 9. An arithmetic-average surface roughness Ra of the lateral surface 27b is higher than an arithmetic-average surface roughness Ra of the upper surface 27a.

A thermal head includes a substrate, a glaze layer, and a reinforced conductor layer. The glaze includes a first glaze and a second glaze. The first glaze extends in a predetermined direction on the surface of the substrate. The second glaze is spaced part from the first glaze to one side in a direction perpendicular to the predetermined direction on the surface of the substrate. The reinforced conductor layer includes a lateral side part. The lateral side part extends on the surface of the substrate from the first glaze side to the second glaze side and is partially located on the second glaze. An edge part on the first glaze side in the second glaze includes a cutout portion cut out toward the one side in the direction perpendicular to the predetermined direction. The lateral side part passes through the cutout portion.

A thermal head includes: an underglaze layer provided on an insulating substrate; an electrode provided on the underglaze layer; a heat generator provided on the electrode; a first protective layer containing a glass material and covering at least the heat generator; and a second protective layer provided on the first protective layer, having a melting point higher than that of the first protective layer, and made of a material whose thermal expansion coefficient at a temperature of 1000 C. or lower is substantially constant.