Multimodal Data

Example Features

This example deploys a developer RAG pipeline for chat Q&A and serves inferencing from NVIDIA API Catalog endpoints instead of NVIDIA Triton Inference Server, a local Llama 2 model, or local GPUs.

Developers get free credits for 10K requests to any of the available models.

The key difference from the Using the NVIDIA API Catalog example is that this example demonstrates how work with multimodal data. The model works with any kind of image in PDF, such as graphs and plots, as well as text and tables.

This example uses models from the NVIDIA API Catalog.

Model

Embedding

Framework

Description

Multi-GPU

TRT-LLM

Model Location

Triton

Vector Database

ai-mixtral-8x7b-instruct for response generation

ai-google-Deplot for graph to text conversion

ai-Neva-22B for image to text conversion

ai-embed-qa-4

Custom Python

QA chatbot

NO

NO

API Catalog

NO

Milvus

The following figure shows the sample topology:

  • The sample chat bot web application communicates with the chain server. The chain server sends inference requests to NVIDIA API Catalog endpoints.

  • Optionally, you can deploy NVIDIA Riva. Riva can use automatic speech recognition to transcribe your questions and use text-to-speech to speak the answers aloud.

Using NVIDIA API Catalog endpoints for inference instead of local components.

Limitations

Although the AI Foundation Models endpoint uses the Neva_22B model for processing images, this example supports uploading images that are part of PDF files only. For example, after deploying the services, you cannot upload a PNG, JPEG, TIFF, or any other image format file.

Prerequisites

  • Clone the Generative AI examples Git repository using Git LFS:

    $ sudo apt -y install git-lfs
$ git clone git@github.com:NVIDIA/GenerativeAIExamples.git
$ cd GenerativeAIExamples/
$ git lfs pull

  • Install Docker Engine and Docker Compose. Refer to the instructions for Ubuntu.

  • Optional: Enable NVIDIA Riva automatic speech recognition (ASR) and text to speech (TTS).

    • To launch a Riva server locally, refer to the Riva Quick Start Guide.

      • In the provided config.sh script, set service_enabled_asr=true and service_enabled_tts=true, and select the desired ASR and TTS languages by adding the appropriate language codes to asr_language_code and tts_language_code.

      • After the server is running, assign its IP address (or hostname) and port (50051 by default) to RIVA_API_URI in deploy/compose/compose.env.

    • Alternatively, you can use a hosted Riva API endpoint. You might need to obtain an API key and/or Function ID for access.

      In deploy/compose/compose.env, make the following assignments as necessary:

      export RIVA_API_URI="<riva-api-address/hostname>:<port>"
export RIVA_API_KEY="<riva-api-key>"
export RIVA_FUNCTION_ID="<riva-function-id>"

Get an API Key for the Mixtral 8x7B Instruct API Endpoint

Perform the following steps if you do not already have an API key. You can use different model API endpoints with the same API key.

  1. Navigate to https://build.nvidia.com/explore/discover.

  2. Find the Mixtral 8x7B Instruct card and click the card.

    Mixtral 8x7B Instruct model card

  3. Click Get API Key.

    API section of the model page.

  4. Click Generate Key.

    Generate key window.

  5. Click Copy Key and then save the API key. The key begins with the letters nvapi-.

    Key Generated widnow.

Build and Start the Containers

  1. In the Generative AI examples repository, edit the deploy/compose/compose.env file.

    Add the API key for the model endpoint:

    export NVIDIA_API_KEY="nvapi-..."

  2. From the root of the repository, build the containers:

    $ docker compose --env-file deploy/compose/compose.env -f deploy/compose/rag-app-multimodal-chatbot.yaml build

  3. Start the containers:

    $ docker compose --env-file deploy/compose/compose.env -f deploy/compose/rag-app-multimodal-chatbot.yaml up -d

    Example Output

     ✔ Network nvidia-rag         Created
 ✔ Container chain-server     Started
 ✔ Container rag-playground   Started

  4. Start the Milvus vector database:

    $ docker compose --env-file deploy/compose/compose.env -f deploy/compose/docker-compose-vectordb.yaml up -d milvus

    Example Output

    ✔ Container milvus-minio       Started
✔ Container milvus-etcd        Started
✔ Container milvus-standalone  Started

  5. Confirm the containers are running:

    $ docker ps --format "table {{.ID}}\t{{.Names}}\t{{.Status}}"

    Example Output

    CONTAINER ID   NAMES               STATUS
37dcdb4ffcb0   rag-playground      Up 3 minutes
39718f6a2a06   chain-server        Up 3 minutes
68af1e4dfb44   milvus-standalone   Up 2 minutes
522b12ec17f0   milvus-minio        Up 2 minutes (healthy)
ed48988c5657   milvus-etcd         Up 2 minutes (healthy)

Next Steps

  • Access the web interface for the chat server. Refer to Using the Sample Chat Web Application for information about using the web interface.

  • Upload one or more PDF files with graphics, plots, and tables.

  • Enable the Use knowledge base checkbox when you submit a question.

  • Stop the containers by running docker compose -f deploy/compose/rag-app-multimodal-chatbot.yaml down and docker compose -f deploy/compose/docker-compose-vectordb.yaml down.