Awesome-omni-skills voice-ai-development
Voice AI Development workflow skill. Use this skill when the user needs Expert in building voice AI applications - from real-time voice and the operator should preserve the upstream workflow, copied support files, and provenance before merging or handing off.
git clone https://github.com/diegosouzapw/awesome-omni-skills
T=$(mktemp -d) && git clone --depth=1 https://github.com/diegosouzapw/awesome-omni-skills "$T" && mkdir -p ~/.claude/skills && cp -r "$T/skills/voice-ai-development" ~/.claude/skills/diegosouzapw-awesome-omni-skills-voice-ai-development && rm -rf "$T"
skills/voice-ai-development/SKILL.mdVoice AI Development
Overview
This public intake copy packages
plugins/antigravity-awesome-skills-claude/skills/voice-ai-developmenthttps://github.com/sickn33/antigravity-awesome-skillsUse it when the operator needs the upstream workflow, support files, and repository context to stay intact while the public validator and private enhancer continue their normal downstream flow.
This intake keeps the copied upstream files intact and uses
metadata.jsonORIGIN.mdVoice AI Development Expert in building voice AI applications - from real-time voice agents to voice-enabled apps. Covers OpenAI Realtime API, Vapi for voice agents, Deepgram for transcription, ElevenLabs for synthesis, LiveKit for real-time infrastructure, and WebRTC fundamentals. Knows how to build low-latency, production-ready voice experiences. Role: Voice AI Architect You are an expert in building real-time voice applications. You think in terms of latency budgets, audio quality, and user experience. You know that voice apps feel magical when fast and broken when slow. You choose the right combination of providers for each use case and optimize relentlessly for perceived responsiveness. ### Expertise - Real-time audio streaming - Voice agent architecture - Provider selection - Latency optimization - Audio quality tuning
Imported source sections that did not map cleanly to the public headings are still preserved below or in the support files. Notable imported sections: Capabilities, Prerequisites, Scope, Ecosystem, Patterns, Validation Checks.
When to Use This Skill
Use this section as the trigger filter. It should make the activation boundary explicit before the operator loads files, runs commands, or opens a pull request.
- User mentions or implies: voice ai
- User mentions or implies: voice agent
- User mentions or implies: speech to text
- User mentions or implies: text to speech
- User mentions or implies: realtime voice
- User mentions or implies: vapi
Operating Table
| Situation | Start here | Why it matters |
|---|---|---|
| First-time use | | Confirms repository, branch, commit, and imported path before touching the copied workflow |
| Provenance review | | Gives reviewers a plain-language audit trail for the imported source |
| Workflow execution | | Starts with the smallest copied file that materially changes execution |
| Supporting context | | Adds the next most relevant copied source file without loading the entire package |
| Handoff decision | | Helps the operator switch to a stronger native skill when the task drifts |
Workflow
This workflow is intentionally editorial and operational at the same time. It keeps the imported source useful to the operator while still satisfying the public intake standards that feed the downstream enhancer flow.
- Confirm the user goal, the scope of the imported workflow, and whether this skill is still the right router for the task.
- Read the overview and provenance files before loading any copied upstream support files.
- Load only the references, examples, prompts, or scripts that materially change the outcome for the current request.
- Execute the upstream workflow while keeping provenance and source boundaries explicit in the working notes.
- Validate the result against the upstream expectations and the evidence you can point to in the copied files.
- Escalate or hand off to a related skill when the work moves out of this imported workflow's center of gravity.
- Before merge or closure, record what was used, what changed, and what the reviewer still needs to verify.
Imported Workflow Notes
Imported: Capabilities
- OpenAI Realtime API
- Vapi voice agents
- Deepgram STT/TTS
- ElevenLabs voice synthesis
- LiveKit real-time infrastructure
- WebRTC audio handling
- Voice agent design
- Latency optimization
Examples
Example 1: Ask for the upstream workflow directly
Use @voice-ai-development to handle <task>. Start from the copied upstream workflow, load only the files that change the outcome, and keep provenance visible in the answer.
Explanation: This is the safest starting point when the operator needs the imported workflow, but not the entire repository.
Example 2: Ask for a provenance-grounded review
Review @voice-ai-development against metadata.json and ORIGIN.md, then explain which copied upstream files you would load first and why.
Explanation: Use this before review or troubleshooting when you need a precise, auditable explanation of origin and file selection.
Example 3: Narrow the copied support files before execution
Use @voice-ai-development for <task>. Load only the copied references, examples, or scripts that change the outcome, and name the files explicitly before proceeding.
Explanation: This keeps the skill aligned with progressive disclosure instead of loading the whole copied package by default.
Example 4: Build a reviewer packet
Review @voice-ai-development using the copied upstream files plus provenance, then summarize any gaps before merge.
Explanation: This is useful when the PR is waiting for human review and you want a repeatable audit packet.
Best Practices
Treat the generated public skill as a reviewable packaging layer around the upstream repository. The goal is to keep provenance explicit and load only the copied source material that materially improves execution.
- Keep the imported skill grounded in the upstream repository; do not invent steps that the source material cannot support.
- Prefer the smallest useful set of support files so the workflow stays auditable and fast to review.
- Keep provenance, source commit, and imported file paths visible in notes and PR descriptions.
- Point directly at the copied upstream files that justify the workflow instead of relying on generic review boilerplate.
- Treat generated examples as scaffolding; adapt them to the concrete task before execution.
- Route to a stronger native skill when architecture, debugging, design, or security concerns become dominant.
Troubleshooting
Problem: The operator skipped the imported context and answered too generically
Symptoms: The result ignores the upstream workflow in
plugins/antigravity-awesome-skills-claude/skills/voice-ai-developmentmetadata.jsonORIGIN.mdProblem: The imported workflow feels incomplete during review
Symptoms: Reviewers can see the generated
SKILL.mdProblem: The task drifted into a different specialization
Symptoms: The imported skill starts in the right place, but the work turns into debugging, architecture, design, security, or release orchestration that a native skill handles better. Solution: Use the related skills section to hand off deliberately. Keep the imported provenance visible so the next skill inherits the right context instead of starting blind.
Related Skills
- Use when the work is better handled by that native specialization after this imported skill establishes context.@trpc-fullstack
- Use when the work is better handled by that native specialization after this imported skill establishes context.@trust-calibrator
- Use when the work is better handled by that native specialization after this imported skill establishes context.@turborepo-caching
- Use when the work is better handled by that native specialization after this imported skill establishes context.@tutorial-engineer
Additional Resources
Use this support matrix and the linked files below as the operator packet for this imported skill. They should reflect real copied source material, not generic scaffolding.
| Resource family | What it gives the reviewer | Example path |
|---|---|---|
| copied reference notes, guides, or background material from upstream | |
| worked examples or reusable prompts copied from upstream | |
| upstream helper scripts that change execution or validation | |
| routing or delegation notes that are genuinely part of the imported package | |
| supporting assets or schemas copied from the source package | |
Imported Reference Notes
Imported: Prerequisites
- 0: Async programming
- 1: WebSocket basics
- 2: Audio concepts (sample rate, codec)
- Required skills: Python or Node.js, API keys for providers, Audio handling knowledge
Imported: Scope
- 0: Latency varies by provider
- 1: Cost per minute adds up
- 2: Quality depends on network
- 3: Complex debugging
Imported: Ecosystem
Primary
- OpenAI Realtime API
- Vapi
- Deepgram
- ElevenLabs
Infrastructure
- LiveKit
- Daily.co
- Twilio
Common_integrations
- WebRTC
- WebSockets
- Telephony (SIP/PSTN)
Platforms
- Web applications
- Mobile apps
- Call centers
- Voice assistants
Imported: Patterns
OpenAI Realtime API
Native voice-to-voice with GPT-4o
When to use: When you want integrated voice AI without separate STT/TTS
import asyncio import websockets import json import base64
OPENAI_API_KEY = "sk-..."
async def voice_session(): url = "wss://api.openai.com/v1/realtime?model=gpt-4o-realtime-preview" headers = { "Authorization": f"Bearer {OPENAI_API_KEY}", "OpenAI-Beta": "realtime=v1" }
async with websockets.connect(url, extra_headers=headers) as ws: # Configure session await ws.send(json.dumps({ "type": "session.update", "session": { "modalities": ["text", "audio"], "voice": "alloy", # alloy, echo, fable, onyx, nova, shimmer "input_audio_format": "pcm16", "output_audio_format": "pcm16", "input_audio_transcription": { "model": "whisper-1" }, "turn_detection": { "type": "server_vad", # Voice activity detection "threshold": 0.5, "prefix_padding_ms": 300, "silence_duration_ms": 500 }, "tools": [ { "type": "function", "name": "get_weather", "description": "Get weather for a location", "parameters": { "type": "object", "properties": { "location": {"type": "string"} } } } ] } })) # Send audio (PCM16, 24kHz, mono) async def send_audio(audio_bytes): await ws.send(json.dumps({ "type": "input_audio_buffer.append", "audio": base64.b64encode(audio_bytes).decode() })) # Receive events async for message in ws: event = json.loads(message) if event["type"] == "response.audio.delta": # Play audio chunk audio = base64.b64decode(event["delta"]) play_audio(audio) elif event["type"] == "response.audio_transcript.done": print(f"Assistant said: {event['transcript']}") elif event["type"] == "input_audio_buffer.speech_started": print("User started speaking") elif event["type"] == "response.function_call_arguments.done": # Handle tool call name = event["name"] args = json.loads(event["arguments"]) result = call_function(name, args) await ws.send(json.dumps({ "type": "conversation.item.create", "item": { "type": "function_call_output", "call_id": event["call_id"], "output": json.dumps(result) } }))
Vapi Voice Agent
Build voice agents with Vapi platform
When to use: Phone-based agents, quick deployment
Vapi provides hosted voice agents with webhooks
from flask import Flask, request, jsonify import vapi
app = Flask(name) client = vapi.Vapi(api_key="...")
Create an assistant
assistant = client.assistants.create( name="Support Agent", model={ "provider": "openai", "model": "gpt-4o", "messages": [ { "role": "system", "content": "You are a helpful support agent..." } ] }, voice={ "provider": "11labs", "voiceId": "21m00Tcm4TlvDq8ikWAM" # Rachel }, firstMessage="Hi! How can I help you today?", transcriber={ "provider": "deepgram", "model": "nova-2" } )
Webhook for conversation events
@app.route("/vapi/webhook", methods=["POST"]) def vapi_webhook(): event = request.json
if event["type"] == "function-call": # Handle tool call name = event["functionCall"]["name"] args = event["functionCall"]["parameters"] if name == "check_order": result = check_order(args["order_id"]) return jsonify({"result": result}) elif event["type"] == "end-of-call-report": # Call ended - save transcript transcript = event["transcript"] save_transcript(event["call"]["id"], transcript) return jsonify({"ok": True})
Start outbound call
call = client.calls.create( assistant_id=assistant.id, customer={ "number": "+1234567890" }, phoneNumber={ "twilioPhoneNumber": "+0987654321" } )
Or create web call
web_call = client.calls.create( assistant_id=assistant.id, type="web" )
Returns URL for WebRTC connection
Deepgram STT + ElevenLabs TTS
Best-in-class transcription and synthesis
When to use: High quality voice, custom pipeline
import asyncio from deepgram import DeepgramClient, LiveTranscriptionEvents from elevenlabs import ElevenLabs
Deepgram real-time transcription
deepgram = DeepgramClient(api_key="...")
async def transcribe_stream(audio_stream): connection = deepgram.listen.live.v("1")
async def on_transcript(result): transcript = result.channel.alternatives[0].transcript if transcript: print(f"Heard: {transcript}") if result.is_final: # Process final transcript await handle_user_input(transcript) connection.on(LiveTranscriptionEvents.Transcript, on_transcript) await connection.start({ "model": "nova-2", # Best quality "language": "en", "smart_format": True, "interim_results": True, # Get partial results "utterance_end_ms": 1000, "vad_events": True, # Voice activity detection "encoding": "linear16", "sample_rate": 16000 }) # Stream audio async for chunk in audio_stream: await connection.send(chunk) await connection.finish()
ElevenLabs streaming synthesis
eleven = ElevenLabs(api_key="...")
def text_to_speech_stream(text: str): """Stream TTS audio chunks.""" audio_stream = eleven.text_to_speech.convert_as_stream( voice_id="21m00Tcm4TlvDq8ikWAM", # Rachel model_id="eleven_turbo_v2_5", # Fastest text=text, output_format="pcm_24000" # Raw PCM for low latency )
for chunk in audio_stream: yield chunk
Or with WebSocket for lowest latency
async def tts_websocket(text_stream): async with eleven.text_to_speech.stream_async( voice_id="21m00Tcm4TlvDq8ikWAM", model_id="eleven_turbo_v2_5" ) as tts: async for text_chunk in text_stream: audio = await tts.send(text_chunk) yield audio
# Flush remaining audio final_audio = await tts.flush() yield final_audio
LiveKit Real-time Infrastructure
WebRTC infrastructure for voice apps
When to use: Building custom real-time voice apps
from livekit import api, rtc import asyncio
Server-side: Create room and tokens
lk_api = api.LiveKitAPI( url="wss://your-livekit.livekit.cloud", api_key="...", api_secret="..." )
async def create_room(room_name: str): room = await lk_api.room.create_room( api.CreateRoomRequest(name=room_name) ) return room
def create_token(room_name: str, participant_name: str): token = api.AccessToken( api_key="...", api_secret="..." ) token.with_identity(participant_name) token.with_grants(api.VideoGrants( room_join=True, room=room_name )) return token.to_jwt()
Agent-side: Connect and process audio
async def voice_agent(room_name: str): room = rtc.Room()
@room.on("track_subscribed") def on_track(track, publication, participant): if track.kind == rtc.TrackKind.KIND_AUDIO: # Process incoming audio audio_stream = rtc.AudioStream(track) asyncio.create_task(process_audio(audio_stream)) token = create_token(room_name, "agent") await room.connect("wss://your-livekit.livekit.cloud", token) # Publish agent's audio source = rtc.AudioSource(sample_rate=24000, num_channels=1) track = rtc.LocalAudioTrack.create_audio_track("agent-voice", source) await room.local_participant.publish_track(track) # Send audio from TTS async def speak(text: str): for audio_chunk in text_to_speech(text): await source.capture_frame(rtc.AudioFrame( data=audio_chunk, sample_rate=24000, num_channels=1, samples_per_channel=len(audio_chunk) // 2 )) return room, speak
Process audio with STT
async def process_audio(audio_stream): async for frame in audio_stream: # Send to Deepgram or other STT await transcriber.send(frame.data)
Full Voice Agent Pipeline
Complete voice agent with all components
When to use: Custom production voice agent
import asyncio from dataclasses import dataclass from typing import AsyncIterator
@dataclass class VoiceAgentConfig: stt_provider: str = "deepgram" tts_provider: str = "elevenlabs" llm_provider: str = "openai" vad_enabled: bool = True interrupt_enabled: bool = True
class VoiceAgent: def init(self, config: VoiceAgentConfig): self.config = config self.is_speaking = False self.conversation_history = []
async def process_audio_stream( self, audio_in: AsyncIterator[bytes], audio_out: asyncio.Queue ): """Main audio processing loop.""" # STT streaming async def transcribe(): transcript_buffer = "" async for audio_chunk in audio_in: # Check for interruption if self.is_speaking and self.config.interrupt_enabled: if await self.detect_speech(audio_chunk): await self.stop_speaking() result = await self.stt.transcribe(audio_chunk) if result.is_final: yield result.transcript # Process transcripts async for user_text in transcribe(): if not user_text.strip(): continue self.conversation_history.append({ "role": "user", "content": user_text }) # Generate response with streaming self.is_speaking = True async for audio_chunk in self.generate_response(user_text): await audio_out.put(audio_chunk) self.is_speaking = False async def generate_response(self, text: str) -> AsyncIterator[bytes]: """Stream LLM response through TTS.""" # Stream LLM tokens llm_stream = self.llm.stream_chat(self.conversation_history) # Buffer for TTS (need ~50 chars for good prosody) text_buffer = "" full_response = "" async for token in llm_stream: text_buffer += token full_response += token # Send to TTS when we have enough text if len(text_buffer) > 50 or token in ".!?": async for audio in self.tts.synthesize_stream(text_buffer): yield audio text_buffer = "" # Flush remaining if text_buffer: async for audio in self.tts.synthesize_stream(text_buffer): yield audio self.conversation_history.append({ "role": "assistant", "content": full_response }) async def detect_speech(self, audio: bytes) -> bool: """Voice activity detection.""" # Use WebRTC VAD or Silero VAD return self.vad.is_speech(audio) async def stop_speaking(self): """Handle interruption.""" self.is_speaking = False # Clear audio queue # Stop TTS generation
Latency optimization tips:
1. Use streaming everywhere (STT, LLM, TTS)
2. Start TTS before LLM finishes (~50 char buffer)
3. Use PCM audio format (no encoding overhead)
4. Keep WebSocket connections alive
5. Use regional endpoints close to users
Imported: Validation Checks
Non-Streaming TTS
Severity: HIGH
Message: Non-streaming TTS adds significant latency.
Fix action: Use tts.synthesize_stream() or tts.convert_as_stream()
Hardcoded Sample Rate
Severity: MEDIUM
Message: Hardcoded sample rate may cause format mismatches.
Fix action: Define sample rates as constants, document expected formats
WebSocket Without Reconnection
Severity: HIGH
Message: WebSocket connections need reconnection logic.
Fix action: Add retry loop with exponential backoff
Missing VAD Configuration
Severity: MEDIUM
Message: VAD needs tuning for good user experience.
Fix action: Configure threshold and silence_duration_ms
Blocking Audio Processing
Severity: HIGH
Message: Audio processing should be async to avoid blocking.
Fix action: Use async def and await for audio operations
Missing Interruption Handling
Severity: MEDIUM
Message: Voice agents should handle user interruptions.
Fix action: Add barge-in detection and cancel current response
Audio Queue Without Clear
Severity: LOW
Message: Audio queues should be clearable for interruptions.
Fix action: Add method to clear queue on interruption
WebSocket Without Error Handling
Severity: HIGH
Message: WebSocket operations need error handling.
Fix action: Wrap in try/except for ConnectionClosed
Imported: Collaboration
Delegation Triggers
- agent graph|workflow|state -> langgraph (Need complex agent logic behind voice)
- extract|structured|json -> structured-output (Need to extract structured data from voice)
- observability|tracing|monitoring -> langfuse (Need to monitor voice agent quality)
- frontend|web|react -> nextjs-app-router (Need web interface for voice agent)
Intelligent Voice Agent
Skills: voice-ai-development, langgraph, structured-output
Workflow:
1. Design agent graph with tools 2. Add voice interface layer 3. Use structured output for tool responses 4. Optimize for voice latency
Monitored Voice Agent
Skills: voice-ai-development, langfuse
Workflow:
1. Build voice agent with provider of choice 2. Add Langfuse callbacks 3. Track latency, quality, conversation flow 4. Iterate based on metrics
Phone-based Agent
Skills: voice-ai-development, twilio
Workflow:
1. Set up Vapi or custom agent 2. Connect to Twilio for PSTN 3. Handle inbound/outbound calls 4. Implement call routing logic
Imported: Limitations
- Use this skill only when the task clearly matches the scope described above.
- Do not treat the output as a substitute for environment-specific validation, testing, or expert review.
- Stop and ask for clarification if required inputs, permissions, safety boundaries, or success criteria are missing.