render-publication-graphic

pjt222

업데이트됨 2 days ago

5 조회

메타design

정보

이 스킬은 인쇄물과 디지털 미디어 모두에 최적화된 출판용 2D 그래픽을 생성합니다. DPI, 색상 프로필, 타이포그래피와 같은 기술적 요구사항을 처리하여 출력물이 출판사 사양을 충족하도록 보장합니다. 개발자는 이를 사용하여 저널, 인쇄물 또는 웹용 단일 소스에서 다중 형식 그래픽을 생성하고 내보낼 수 있습니다.

빠른 설치

Claude Code

문서

Render Publication Graphic

Produce publication-ready graphics that meet technical requirements for academic journals, books, presentations, and web publication. Covers DPI requirements, color space management, typography best practices, file format selection, and metadata embedding.

Cuándo Usar

Preparing figures for academic journal submission
Creating graphics for print publications (books, magazines)
Generating high-quality assets for presentations
Exporting visualizations for web publication with proper optimization
Ensuring graphics meet publisher technical specifications
Archiving graphics with proper metadata
Creating multi-format exports from single source

Entradas

Input	Type	Description	Example
Source graphic	File/Data	Original visualization or artwork	SVG, R ggplot, Python matplotlib, Blender render
Publication target	Specification	Journal, web, print, presentation	Nature journal, IEEE paper, website
Technical requirements	Parameters	DPI, dimensions, color space, format	300 DPI, 180mm width, CMYK, TIFF
Style guide	Document	Publisher typography and formatting rules	Font families, line widths, color palette
Metadata	Information	Title, author, date, copyright, description	Figure caption, license info

Procedimiento

1. Determine Output Requirements

Identify technical specifications for target publication:

# Common publication requirements

academic_journal:
  dpi: 300-600
  format: TIFF, EPS, PDF
  color_space: RGB or CMYK (check guidelines)
  max_width: 180mm (single column) or 390mm (double column)
  fonts: Embed or outline
  resolution_minimums:
    line_art: 1000 DPI
    halftone: 300 DPI
    combination: 600 DPI

web_publication:
  dpi: 72-96 (retina: 144-192)
  format: PNG, WebP, SVG
  color_space: sRGB
  max_file_size: 200KB-500KB
  optimization: Compress, progressive loading

presentation:
  dpi: 96-150
  format: PNG, PDF, SVG
  color_space: RGB
  dimensions: 16:9 or 4:3 aspect ratio
  contrast: High contrast for projectors

print_book:
  dpi: 300-600
  format: TIFF, PDF/X
  color_space: CMYK
  bleed: 3-5mm beyond trim
  fonts: Embedded

Esperado: Clear understanding of target requirements En caso de fallo: Contact publisher for specific guidelines, use conservative defaults

2. Set Correct DPI for Raster Graphics

Configure resolution based on output medium:

from PIL import Image

def set_dpi_pillow(image_path, output_path, target_dpi=300):
    """Set DPI metadata for PNG/TIFF."""
    img = Image.open(image_path)

    # Save with DPI metadata
    img.save(output_path, dpi=(target_dpi, target_dpi))
    print(f"Saved with {target_dpi} DPI: {output_path}")

def calculate_dimensions(width_mm, height_mm, dpi=300):
    """Calculate pixel dimensions from physical size."""
    # Convert mm to inches
    width_inches = width_mm / 25.4
    height_inches = height_mm / 25.4

    # Calculate pixels
    width_px = int(width_inches * dpi)
    height_px = int(height_inches * dpi)

    return width_px, height_px

# Example: 180mm wide figure at 300 DPI
width, height = calculate_dimensions(180, 120, dpi=300)
print(f"Required resolution: {width}x{height} pixels")
# Output: Required resolution: 2126x1417 pixels

# R ggplot2 export with proper DPI
library(ggplot2)

# Create plot
p <- ggplot(mtcars, aes(x = wt, y = mpg)) +
  geom_point() +
  theme_minimal(base_size = 12)

# Save for publication (300 DPI)
ggsave(
  filename = "figure1.png",
  plot = p,
  width = 180,
  height = 120,
  units = "mm",
  dpi = 300
)

# Save as vector for flexibility
ggsave(
  filename = "figure1.pdf",
  plot = p,
  width = 180,
  height = 120,
  units = "mm",
  device = cairo_pdf  # Better text rendering
)

Esperado: Graphics rendered at correct resolution for print quality En caso de fallo: Verify DPI metadata saved correctly, check file size appropriate

3. Configure Color Space

Set appropriate color profile:

from PIL import Image, ImageCms

def convert_to_cmyk(rgb_image_path, cmyk_output_path):
    """Convert RGB to CMYK for print."""
    img = Image.open(rgb_image_path)

    if img.mode != 'RGB':
        img = img.convert('RGB')

    # Convert to CMYK
    cmyk_img = img.convert('CMYK')
    cmyk_img.save(cmyk_output_path, format='TIFF', compression='tiff_lzw')
    print(f"Converted to CMYK: {cmyk_output_path}")

def apply_srgb_profile(image_path, output_path):
    """Apply sRGB profile for web."""
    img = Image.open(image_path)

    # sRGB profile (embedded in Pillow)
    srgb_profile = ImageCms.createProfile('sRGB')

    # Convert to sRGB
    img_srgb = ImageCms.profileToProfile(
        img,
        srgb_profile,
        srgb_profile,
        renderingIntent=ImageCms.Intent.PERCEPTUAL
    )

    img_srgb.save(output_path)

# ImageMagick for color space conversion
convert input.png -colorspace sRGB output_srgb.png
convert input.png -colorspace CMYK output_cmyk.tiff

# Check color profile
identify -verbose image.png | grep -i colorspace

Esperado: Color space matches publication requirements En caso de fallo: Verify color profile embedded, test print preview

4. Configure Typography

Ensure text is readable and properly formatted:

from PIL import ImageFont

def get_publication_fonts():
    """Load fonts appropriate for publication."""
    # Common publication-safe fonts
    fonts = {
        'serif': 'Times New Roman',
        'sans': 'Arial',
        'mono': 'Courier New'
    }

    try:
        # Load with proper size for DPI
        # At 300 DPI, 12pt = 12 * 300/72 = 50 pixels
        base_size_300dpi = 50

        font_regular = ImageFont.truetype(f"{fonts['sans']}.ttf", base_size_300dpi)
        font_bold = ImageFont.truetype(f"{fonts['sans']} Bold.ttf", base_size_300dpi)

        return {'regular': font_regular, 'bold': font_bold}
    except:
        return {'regular': ImageFont.load_default(), 'bold': ImageFont.load_default()}

# Typography guidelines
typography_specs = {
    'minimum_font_size': '8pt',  # Readable when printed
    'line_width_min': 0.5,  # Points, for print clarity
    'panel_labels': {
        'font': 'Arial Bold',
        'size': '12pt',
        'position': 'top-left',
        'style': 'A, B, C'  # Or (a), (b), (c)
    },
    'axis_labels': {
        'font': 'Arial',
        'size': '10pt'
    },
    'legend': {
        'font': 'Arial',
        'size': '9pt',
        'position': 'outside plot area'
    }
}

# R publication-quality typography
library(ggplot2)

p <- ggplot(mtcars, aes(x = wt, y = mpg)) +
  geom_point(size = 2) +
  labs(
    title = "Fuel Efficiency vs Weight",
    x = "Weight (1000 lbs)",
    y = "Miles per Gallon"
  ) +
  theme_bw(base_size = 12, base_family = "Arial") +
  theme(
    plot.title = element_text(size = 14, face = "bold"),
    axis.title = element_text(size = 12),
    axis.text = element_text(size = 10),
    legend.text = element_text(size = 10),
    panel.grid.minor = element_blank(),
    # Ensure text is black for print
    text = element_text(color = "black")
  )

Esperado: Text readable at publication size, fonts embedded properly En caso de fallo: Increase font sizes, check font licensing, convert text to outlines

5. Select Appropriate File Format

Choose format based on use case:

def export_multi_format(source_path, output_base, formats=['png', 'pdf', 'tiff']):
    """Export graphic in multiple formats."""
    from PIL import Image
    import cairosvg
    import os

    base, ext = os.path.splitext(output_base)

    if ext.lower() in ['.svg']:
        # SVG source - convert to rasters
        for fmt in formats:
            output = f"{base}.{fmt}"

            if fmt == 'png':
                cairosvg.svg2png(
                    url=source_path,
                    write_to=output,
                    output_width=2126,  # 180mm @ 300 DPI
                    output_height=1417   # 120mm @ 300 DPI
                )
            elif fmt == 'pdf':
                cairosvg.svg2pdf(url=source_path, write_to=output)
            elif fmt == 'tiff':
                # Convert via PNG intermediate
                temp_png = f"{base}_temp.png"
                cairosvg.svg2png(url=source_path, write_to=temp_png)
                img = Image.open(temp_png)
                img.save(output, format='TIFF', compression='tiff_lzw')
                os.remove(temp_png)

    else:
        # Raster source
        img = Image.open(source_path)

        for fmt in formats:
            output = f"{base}.{fmt}"

            if fmt == 'png':
                img.save(output, format='PNG', dpi=(300, 300), optimize=True)
            elif fmt == 'tiff':
                img.save(output, format='TIFF', compression='tiff_lzw', dpi=(300, 300))
            elif fmt == 'pdf':
                # Use img2pdf or similar for raster-to-PDF
                img.save(output, format='PDF', resolution=300.0)

    print(f"Exported in formats: {', '.join(formats)}")

# Format selection guide
format_guide = {
    'TIFF': {
        'use_for': 'Journal submission, archival',
        'benefits': 'Lossless, supports CMYK, high quality',
        'compression': 'LZW or ZIP (lossless)'
    },
    'PDF': {
        'use_for': 'Submission, print, archival',
        'benefits': 'Vector or raster, text searchable, widely accepted',
        'variants': 'PDF/A (archival), PDF/X (print)'
    },
    'PNG': {
        'use_for': 'Web, presentations, digital',
        'benefits': 'Lossless, transparency, good compression',
        'limitation': 'RGB only, larger than JPEG'
    },
    'SVG': {
        'use_for': 'Web, further editing, scalable graphics',
        'benefits': 'Vector, infinitely scalable, small file size',
        'limitation': 'Not always accepted by journals'
    },
    'EPS': {
        'use_for': 'Legacy journal requirements',
        'benefits': 'Vector format accepted by older systems',
        'limitation': 'Being phased out, use PDF instead'
    }
}

Esperado: Appropriate format for publication channel En caso de fallo: Check publisher requirements, provide multiple formats

6. Optimize for Web

Create web-optimized versions:

def optimize_for_web(input_path, output_path, max_width=1200, quality=85):
    """Optimize image for web publication."""
    from PIL import Image

    img = Image.open(input_path)

    # Resize if too large
    if img.width > max_width:
        ratio = max_width / img.width
        new_height = int(img.height * ratio)
        img = img.resize((max_width, new_height), Image.LANCZOS)

    # Convert to RGB if needed
    if img.mode in ('RGBA', 'LA', 'P'):
        background = Image.new('RGB', img.size, (255, 255, 255))
        if img.mode == 'P':
            img = img.convert('RGBA')
        background.paste(img, mask=img.split()[-1] if 'A' in img.mode else None)
        img = background

    # Save optimized
    img.save(output_path, format='JPEG', quality=quality, optimize=True, progressive=True)

    # Check file size
    import os
    file_size_kb = os.path.getsize(output_path) / 1024
    print(f"Optimized: {file_size_kb:.1f} KB")

def create_responsive_set(input_path, output_base):
    """Create multiple resolutions for responsive web."""
    from PIL import Image

    img = Image.open(input_path)
    sizes = [
        (640, '640w'),
        (1024, '1024w'),
        (1920, '1920w')
    ]

    for width, suffix in sizes:
        if img.width >= width:
            ratio = width / img.width
            height = int(img.height * ratio)
            resized = img.resize((width, height), Image.LANCZOS)

            output = f"{output_base}_{suffix}.jpg"
            resized.save(output, format='JPEG', quality=85, optimize=True)

Esperado: Web-optimized images under 500KB, responsive sizes generated En caso de fallo: Reduce quality, resize further, consider WebP format

7. Embed Metadata

Add descriptive metadata for archival:

from PIL import Image
from PIL.PngImagePlugin import PngInfo

def embed_metadata(image_path, output_path, metadata):
    """Embed metadata in PNG."""
    img = Image.open(image_path)

    # Create metadata
    png_info = PngInfo()
    for key, value in metadata.items():
        png_info.add_text(key, str(value))

    # Save with metadata
    img.save(output_path, format='PNG', pnginfo=png_info)

# Example metadata
metadata = {
    'Title': 'Figure 1: Relationship between weight and fuel efficiency',
    'Author': 'Jane Doe',
    'Description': 'Scatter plot showing negative correlation',
    'Copyright': 'CC-BY 4.0',
    'Software': 'R 4.3.0, ggplot2 3.4.0',
    'Creation Date': '2026-02-16',
    'Source': 'mtcars dataset'
}

embed_metadata('figure1.png', 'figure1_with_metadata.png', metadata)

Esperado: Metadata embedded and retrievable En caso de fallo: Check format supports metadata (PNG, TIFF, PDF yes; JPEG limited)

Validación

Errores Comunes

Insufficient resolution: 72 DPI web graphics cannot be printed at quality
Wrong color space: RGB graphics may print differently than displayed
Font substitution: Non-embedded fonts replaced with defaults
Small text: Fonts below 8pt may be illegible when printed
Thin lines: Lines below 0.5pt may not print clearly
File size: High DPI graphics can be very large, compress appropriately
Compression artifacts: JPEG compression unsuitable for line art or text
Missing bleed: Print graphics need 3-5mm bleed beyond trim
Transparency issues: Some formats don't preserve transparency correctly
Aspect ratio: Distortion from incorrect dimension calculations

Habilidades Relacionadas

create-2d-composition: Creating the source graphics
render-blender-output: 3D rendering settings for publication
generate-quarto-report: Integrating graphics into documents

GitHub 저장소

pjt222/agent-almanac

경로: i18n/es/skills/render-publication-graphic

agentsagentskillsai-assisted-developmentclaude-codeskillsteams

연관 스킬

content-collections

메타

이 스킬은 콘텐츠 콜렉션(Content Collections)을 위한 프로덕션 검증된 설정을 제공합니다. 콘텐츠 콜렉션은 Markdown/MDX 파일을 Zod 검증이 포함된 타입 안전한 데이터 콜렉션으로 변환해주는 TypeScript 최우선 도구입니다. 블로그, 문서 사이트 또는 콘텐츠 중심의 Vite + React 애플리케이션을 구축할 때 타입 안전성과 자동 콘텐츠 검증을 보장하기 위해 사용하세요. Vite 플러그인 구성과 MDX 컴파일부터 배포 최적화 및 스키마 검증에 이르기까지 모든 것을 다룹니다.

스킬 보기

polymarket

메타

이 스킬은 개발자들이 Polymarket 예측 시장 플랫폼을 활용한 애플리케이션을 구축할 수 있도록 지원하며, 거래 및 시장 데이터를 위한 API 통합 기능을 포함합니다. 또한 WebSocket을 통한 실시간 데이터 스트리밍을 제공하여 실시간 거래와 시장 활동을 모니터링할 수 있습니다. 이를 통해 거래 전략을 구현하거나 실시간 시장 업데이트를 처리하는 도구를 생성하는 데 활용할 수 있습니다.

스킬 보기

creating-opencode-plugins

메타

이 스킬은 개발자들이 명령어, 파일, LSP 작업 등 25개 이상의 이벤트 유형에 연결되는 OpenCode 플러그인을 만들 수 있도록 돕습니다. JavaScript/TypeScript 모듈을 위한 플러그인 구조, 이벤트 API 명세, 구현 패턴을 제공합니다. OpenCode AI 어시스턴트의 라이프사이클을 사용자 정의 이벤트 기반 로직으로 가로채거나, 모니터링하거나, 확장해야 할 때 사용하세요.

스킬 보기

sglang

메타

SGLang은 RadixAttention 프리픽스 캐싱을 활용하여 JSON, 정규식, 에이전트 워크플로우를 위한 고속 구조화 생성에 특화된 고성능 LLM 서빙 프레임워크입니다. 특히 반복되는 프리픽스가 있는 작업에서 상당히 빠른 추론 속도를 제공하여 복잡한 구조화 출력 및 다중 턴 대화에 이상적입니다. 제약 디코딩이 필요하거나 광범위한 프리픽스 공유가 있는 애플리케이션을 구축할 때는 vLLM과 같은 대안보다 SGLang을 선택하십시오.

스킬 보기