v1.11.0: CCS811 en daemon + fix filtrage + I2C 10kHz requis

Vérif terrain sur pro100 : à 100 kHz le CCS811 renvoie des valeurs corrompues 0x8000 (32768) par clock-stretching, et le modèle oneshot-reset-toutes-les-10s ne donne que le 1er échantillon post-init (garbage). Refonte : - CCS811/daemon.py: service long-running (Type=simple, Restart=always). Init 1x, boucle lecture/écriture 10s, filtre eCO2 dans [400,8192], re-init auto sur erreurs I2C répétées. Remplace write_data.py (supprimé). - CCS811/get_data.py: lit la dernière ligne data_CCS811 au lieu du capteur (évite la collision I2C avec le daemon -> corruption observée). - setup_services.sh: service daemon + self-heal suppression de l'ancien .timer; activation hors boucle timers. - launcher.php: .timer -> .service (map statut + allowedServices x2). - update_firmware.sh: redémarre le daemon à l'OTA. - doc: README (archi daemon + I2C 10kHz confirmé requis), CLAUDE.md, changelog. Co-Authored-By: Claude Opus 4.8 (1M context) <noreply@anthropic.com>
2026-06-02 16:08:03 +02:00
parent 46c73acb7e
commit 13c266d694
10 changed files with 240 additions and 211 deletions
--- a/CCS811/README.md
+++ b/CCS811/README.md
@@ -26,8 +26,12 @@ mitigation, les lectures échouent typiquement en `OSError` / `Remote I/O error`
 dtparam=i2c_arm_baudrate=10000
 ```
-(10 kHz au lieu de 100 kHz par défaut.) Reboot ensuite. À valider au bench — sur
+(10 kHz au lieu de 100 kHz par défaut.) Reboot ensuite.
-certains modules/CM4 ça passe à 100 kHz, sur d'autres non.
+
 **Confirmé nécessaire sur le terrain** (nebuleair-pro100, juin 2026) : à 100 kHz le
 CCS811 renvoie des valeurs corrompues 0x8000+ (32768) par intermittence et finit en
 état d'erreur. À 10 kHz c'est stable. Ce réglage n'est pas géré par le repo (fichier
 hors `/var/www`), il doit être posé à la main sur chaque capteur équipé d'un CCS811.
 Vérifier la présence du capteur :
@@ -64,20 +68,34 @@ sans level-shifter sauf si le module embarque son propre régulateur + shifter.
 ## Implémentation NebuleAir
- `CCS811/get_data.py` — lecture live (bouton "Get Data" du web). Affiche
+⚠ **Architecture : daemon, PAS un timer oneshot** (contrairement aux autres capteurs).
-  `{"eCO2": <ppm>, "TVOC": <ppb>}` ou `{"error": "..."}`.
+Le CCS811 doit être initialisé **une seule fois** puis lu en continu :
 - `CCS811/write_data.py` — lecture périodique (timer systemd, toutes les 10 s),
  écrit dans la table `data_CCS811 (timestamp, eCO2, TVOC)`.
-Librairie Python : `adafruit-circuitpython-ccs811` (installée par
+- chaque (ré)init fait un reset + app_start, et les premiers échantillons juste après
-`installation_part1.sh`). La table est créée par `sqlite/create_db.py` et
+  sont du garbage (eCO2 = 0, ou valeurs 0x8000+ = 32768 dues au clock-stretching) ;
-self-healée par `write_data.py` (CREATE TABLE IF NOT EXISTS) — garder les deux
+- un cycle reset toutes les 10 s empêche l'algorithme de baseline de se construire.
-schémas synchro.
+
 Composants :
 - `CCS811/daemon.py` — service long-running (`nebuleair-ccs811-data.service`,
  `Type=simple`, `Restart=always`). Init une fois, puis boucle : toutes les 10 s,
  lit un échantillon **valide** (eCO2 ∈ [400, 8192], le reste est jeté) et l'écrit
  dans `data_CCS811 (timestamp, eCO2, TVOC)`. Re-init automatique du capteur après
  plusieurs erreurs I2C consécutives.
 - `CCS811/get_data.py` — bouton "Get Data" du web. **Ne lit PAS le capteur** (ça
  entrerait en collision I2C avec le daemon et corromprait la sonde) : renvoie la
  **dernière ligne** de `data_CCS811`. Affiche `{"eCO2","TVOC","timestamp"}` ou
  `{"error": "..."}`.
 Librairie Python : `adafruit-circuitpython-ccs811` (dans `requirements.txt`,
 installée par `installation_part1.sh` ET par `update_firmware.sh`). La table est
 créée par `sqlite/create_db.py` et self-healée par `daemon.py`
 (CREATE TABLE IF NOT EXISTS) — garder les deux schémas synchro.
 Activation : `admin.html` → case "Send VOC sensor data (CCS811)".
 ### Pistes d'amélioration (non implémentées)
 Le CCS811 supporte une compensation température/humidité (`SET_ENV_DATA`). Comme le
-boîtier embarque déjà un BME280, on pourrait lui pousser temp/hum à chaque lecture
+boîtier embarque déjà un BME280, on pourrait lui pousser temp/hum périodiquement
-pour améliorer la précision. Non fait en v1 pour garder le script simple et autonome.
+pour améliorer la précision. Non fait pour garder le daemon simple.
--- a/CCS811/daemon.py
+++ b/CCS811/daemon.py
@@ -0,0 +1,143 @@
 '''
 Long-running daemon for the AMS CCS811 air-quality sensor (TVOC + eCO2).
 Run by systemd nebuleair-ccs811-data.service (Type=simple, Restart=always).
 WHY a daemon and not a 10s oneshot timer like the other sensors:
 the CCS811 must be initialised ONCE and then read continuously. Each driver
 (re)init does a reset + app_start, and the first samples right after that are
 garbage (eCO2 = 0 or 0x8000+ corruption). Resetting every 10s also prevents the
 sensor's baseline algorithm from ever building up. So we init once here and loop.
 Valid eCO2 range is [400, 8192] ppm. Out-of-range samples (notably 0x8000 = 32768,
 an I2C clock-stretching corruption artifact on the Pi) are dropped.
 TVOC is the primary measurement; eCO2 is *derived* from VOCs (not a true NDIR CO2).
 The web "Get Data" button does NOT read the sensor (that would collide with this
 daemon on the I2C bus and corrupt it) — it reads the last row from the DB instead.
 See CCS811/get_data.py.
 '''
 import sqlite3
 import sys
 import time
 DB_PATH = "/var/www/nebuleair_pro_4g/sqlite/sensors.db"
 DEFAULT_ADDRESS = 0x5A
 READ_INTERVAL = 10        # seconds between stored samples
 ECO2_MIN, ECO2_MAX = 400, 8192   # CCS811 physical eCO2 range
 SAMPLE_TIMEOUT = 4        # max seconds to wait for a valid sample within a tick
 REINIT_AFTER_ERRORS = 5   # consecutive I2C errors before re-initialising the sensor
 INIT_RETRY_DELAY = 10     # seconds between init attempts
 def get_config(cursor, key, default):
    cursor.execute("SELECT value FROM config_table WHERE key = ?", (key,))
    row = cursor.fetchone()
    return row[0] if row else default
 def ensure_table(cursor):
    # Self-heal: duplicates the canonical schema from sqlite/create_db.py.
    cursor.execute("""
        CREATE TABLE IF NOT EXISTS data_CCS811 (
            timestamp TEXT,
            eCO2 INTEGER,
            TVOC INTEGER
        )
    """)
 def init_sensor(address):
    import board
    import busio
    import adafruit_ccs811
    i2c = busio.I2C(board.SCL, board.SDA)
    return adafruit_ccs811.CCS811(i2c, address=address)
 def init_with_retry(address):
    while True:
        try:
            ccs = init_sensor(address)
            print(f"CCS811: initialised at {hex(address)}", flush=True)
            return ccs
        except Exception as e:
            print(f"CCS811: init failed at {hex(address)}: {e} (retry in {INIT_RETRY_DELAY}s)", flush=True)
            time.sleep(INIT_RETRY_DELAY)
 def read_valid_sample(ccs):
    '''Poll up to SAMPLE_TIMEOUT for a data_ready sample in the valid eCO2 range.
    Returns (eco2, tvoc) or None. Raises OSError on I2C failure.'''
    end = time.monotonic() + SAMPLE_TIMEOUT
    while time.monotonic() < end:
        if ccs.data_ready:
            eco2 = int(ccs.eco2)
            tvoc = int(ccs.tvoc)
            if ECO2_MIN <= eco2 <= ECO2_MAX:
                return eco2, tvoc
            # else: out-of-range (warm-up 0 or 0x8000 corruption) -> keep polling
        time.sleep(0.5)
    return None
 def main():
    conn = sqlite3.connect(DB_PATH, timeout=10)
    cursor = conn.cursor()
    ensure_table(cursor)
    conn.commit()
    addr_str = get_config(cursor, "CCS811_address", "0x5A")
    try:
        address = int(str(addr_str), 16)
    except ValueError:
        address = DEFAULT_ADDRESS
    try:
        import board  # noqa: F401
        import busio  # noqa: F401
        import adafruit_ccs811  # noqa: F401
    except Exception as e:
        print(f"CCS811: library import failed: {e}", flush=True)
        conn.close()
        sys.exit(1)
    ccs = init_with_retry(address)
    print("CCS811: discarding warm-up samples...", flush=True)
    consecutive_errors = 0
    while True:
        try:
            sample = read_valid_sample(ccs)
            consecutive_errors = 0
            if sample is None:
                print("CCS811: no valid sample this tick (warming up or corrupted), skipping.", flush=True)
            else:
                eco2, tvoc = sample
                cursor.execute("SELECT last_updated FROM timestamp_table LIMIT 1")
                row = cursor.fetchone()
                rtc_time_str = row[0] if row else "not connected"
                cursor.execute(
                    "INSERT INTO data_CCS811 (timestamp, eCO2, TVOC) VALUES (?, ?, ?)",
                    (rtc_time_str, eco2, tvoc),
                )
                conn.commit()
                print(f"eCO2: {eco2} ppm, TVOC: {tvoc} ppb (saved at {rtc_time_str})", flush=True)
        except OSError as e:
            consecutive_errors += 1
            print(f"CCS811: I2C error: {e} (#{consecutive_errors})", flush=True)
            if consecutive_errors >= REINIT_AFTER_ERRORS:
                print("CCS811: too many I2C errors, re-initialising sensor...", flush=True)
                ccs = init_with_retry(address)
                consecutive_errors = 0
        except Exception as e:
            print(f"CCS811: unexpected error: {e}", flush=True)
        time.sleep(READ_INTERVAL)
 if __name__ == "__main__":
    main()
--- a/CCS811/get_data.py
+++ b/CCS811/get_data.py
@@ -1,90 +1,39 @@
 '''
-Live read of the AMS CCS811 air-quality sensor (used by the web "Get Data" button).
+Live value for the web "Get Data" button (CCS811 air-quality sensor).
-Prints a JSON object: {"eCO2": <int_ppm>, "TVOC": <int_ppb>} or {"error": "<message>"}.
+Prints {"eCO2": <ppm>, "TVOC": <ppb>, "timestamp": <str>} or {"error": "<msg>"}.
-CCS811 is a MOX gas sensor: it outputs an equivalent CO2 (eCO2, derived from VOCs)
+IMPORTANT: this does NOT read the I2C sensor. The CCS811 is owned by the
-and a Total VOC (TVOC). It is NOT an NDIR CO2 sensor like the S88. TVOC is the
+long-running daemon (CCS811/daemon.py); opening the bus here would collide with
-primary measurement of interest here.
+it and corrupt the sensor. Instead we return the most recent row the daemon
 stored in data_CCS811. TVOC is the primary measurement.
-I2C, library adafruit-circuitpython-ccs811. Address read from config_table
+Usage: /usr/bin/python3 /var/www/nebuleair_pro_4g/CCS811/get_data.py
 (key CCS811_address, e.g. "0x5A" Adafruit / "0x5B" SparkFun), default 0x5A.
 Usage: /usr/bin/python3 /var/www/nebuleair_pro_4g/CCS811/get_data.py [address]
 '''
 import json
 import sqlite3
 import sys
 import time
 DB_PATH = "/var/www/nebuleair_pro_4g/sqlite/sensors.db"
 DEFAULT_ADDRESS = 0x5A
 # CCS811 produces a fresh sample every 1 s in drive mode 1. Poll data_ready a few
 # times to cover the case where the driver was just (re)initialised.
 DATA_READY_RETRIES = 30
 DATA_READY_DELAY = 0.2  # seconds
 def get_address_from_config():
    try:
        conn = sqlite3.connect(DB_PATH)
        cursor = conn.cursor()
        cursor.execute("SELECT value FROM config_table WHERE key = ?", ("CCS811_address",))
        row = cursor.fetchone()
        conn.close()
        if row and row[0]:
            return int(str(row[0]), 16)
    except Exception:
        pass
    return DEFAULT_ADDRESS
 def main():
    if len(sys.argv) > 1:
    try:
-            address = int(sys.argv[1], 16)
+        conn = sqlite3.connect(DB_PATH, timeout=5)
-        except ValueError:
+        cursor = conn.cursor()
-            print(json.dumps({"error": f"invalid address {sys.argv[1]}"}))
+        cursor.execute(
-            return
+            "SELECT timestamp, eCO2, TVOC FROM data_CCS811 ORDER BY timestamp DESC LIMIT 1"
-    else:
+        )
-        address = get_address_from_config()
+        row = cursor.fetchone()
-
+        conn.close()
    try:
        import board
        import busio
        import adafruit_ccs811
    except Exception as e:
-        print(json.dumps({"error": f"library import failed: {e}"}))
+        print(json.dumps({"error": f"DB read error: {e}"}))
        return
-    try:
+    if not row:
-        i2c = busio.I2C(board.SCL, board.SDA)
+        print(json.dumps({"error": "No CCS811 data yet (daemon warming up?)"}))
        ccs811 = adafruit_ccs811.CCS811(i2c, address=address)
    except Exception as e:
        print(json.dumps({"error": f"cannot init CCS811 at {hex(address)}: {e}"}))
        return
-    try:
+    print(json.dumps({"timestamp": row[0], "eCO2": int(row[1]), "TVOC": int(row[2])}))
        ready = False
        for _ in range(DATA_READY_RETRIES):
            if ccs811.data_ready:
                ready = True
                break
            time.sleep(DATA_READY_DELAY)
        if not ready:
            print(json.dumps({"error": "CCS811 data not ready (warming up?)"}))
            return
        eco2 = int(ccs811.eco2)
        tvoc = int(ccs811.tvoc)
        # eCO2 floor is 400 ppm; a sub-400 value is a not-yet-settled sample.
        if eco2 < 400:
            print(json.dumps({"error": "CCS811 reading not settled (warming up?)"}))
            return
        print(json.dumps({"eCO2": eco2, "TVOC": tvoc}))
    except Exception as e:
        print(json.dumps({"error": f"CCS811 read error: {e}"}))
 if __name__ == "__main__":
--- a/CCS811/write_data.py
+++ b/CCS811/write_data.py
@@ -1,105 +0,0 @@
 '''
 Script to get air-quality values from the AMS CCS811 sensor and write to database.
 /usr/bin/python3 /var/www/nebuleair_pro_4g/CCS811/write_data.py
 CCS811 is a MOX gas sensor: eCO2 (equivalent CO2 in ppm, derived from VOCs) and
 TVOC (Total VOC in ppb). TVOC is the primary measurement of interest.
 I2C, library adafruit-circuitpython-ccs811. Address from config_table
 (key CCS811_address, e.g. "0x5A" / "0x5B"), default 0x5A.
 '''
 import sqlite3
 import sys
 import time
 DB_PATH = "/var/www/nebuleair_pro_4g/sqlite/sensors.db"
 DEFAULT_ADDRESS = 0x5A
 DATA_READY_RETRIES = 30
 DATA_READY_DELAY = 0.2  # seconds
 def get_config(cursor, key, default):
    cursor.execute("SELECT value FROM config_table WHERE key = ?", (key,))
    row = cursor.fetchone()
    return row[0] if row else default
 def main():
    conn = sqlite3.connect(DB_PATH)
    cursor = conn.cursor()
    # Self-heal: ensure the table exists even if create_db.py was skipped during OTA.
    # Duplicates the canonical schema from sqlite/create_db.py — keep them in sync.
    cursor.execute("""
        CREATE TABLE IF NOT EXISTS data_CCS811 (
            timestamp TEXT,
            eCO2 INTEGER,
            TVOC INTEGER
        )
    """)
    conn.commit()
    addr_str = get_config(cursor, "CCS811_address", "0x5A")
    try:
        address = int(str(addr_str), 16)
    except ValueError:
        address = DEFAULT_ADDRESS
    try:
        import board
        import busio
        import adafruit_ccs811
    except Exception as e:
        print(f"CCS811: library import failed: {e}")
        conn.close()
        sys.exit(1)
    try:
        i2c = busio.I2C(board.SCL, board.SDA)
        ccs811 = adafruit_ccs811.CCS811(i2c, address=address)
    except Exception as e:
        print(f"CCS811: cannot init at {hex(address)}: {e}")
        conn.close()
        sys.exit(1)
    try:
        ready = False
        for _ in range(DATA_READY_RETRIES):
            if ccs811.data_ready:
                ready = True
                break
            time.sleep(DATA_READY_DELAY)
        if not ready:
            print("CCS811: data not ready (warming up?), skipping.")
            return
        eco2 = int(ccs811.eco2)
        tvoc = int(ccs811.tvoc)
        # eCO2 has a physical floor of 400 ppm. Just after the driver (re)inits,
        # the CCS811 can return a 0/0 sample before its first valid measurement is
        # ready — those are spurious, drop them (next 10 s tick will retry).
        if eco2 < 400:
            print(f"CCS811: reading not settled (eCO2={eco2}), skipping.")
            return
        cursor.execute("SELECT last_updated FROM timestamp_table LIMIT 1")
        row = cursor.fetchone()
        rtc_time_str = row[0]
        cursor.execute(
            "INSERT INTO data_CCS811 (timestamp, eCO2, TVOC) VALUES (?, ?, ?)",
            (rtc_time_str, eco2, tvoc),
        )
        conn.commit()
        print(f"eCO2: {eco2} ppm, TVOC: {tvoc} ppb (saved at {rtc_time_str})")
    except Exception as e:
        print(f"CCS811 error: {e}")
    finally:
        conn.close()
 if __name__ == "__main__":
    main()
--- a/CLAUDE.md
+++ b/CLAUDE.md
@@ -104,7 +104,7 @@ sudo /var/www/nebuleair_pro_4g/services/setup_services.sh
 - `nebuleair-envea-data.timer`: Every 10 seconds (Envea sensors)
 - `nebuleair-sara-data.timer`: Every 60 seconds (4G data transmission)
 - `nebuleair-bme280-data.timer`: Every 120 seconds (BME280 sensor)
- `nebuleair-ccs811-data.timer`: Every 10 seconds (CCS811 TVOC/eCO2 sensor)
+- `nebuleair-ccs811-data.service`: Daemon, continuous (CCS811 TVOC/eCO2 sensor — init once, reads every 10s; not a oneshot timer because the CCS811 must run continuously)
 - `nebuleair-mppt-data.timer`: Every 120 seconds (MPPT charger)
 - `nebuleair-noise-data.timer`: Every 60 seconds (Noise sensor)
 - `nebuleair-db-cleanup-data.timer`: Daily (database cleanup)
--- a/2
+++ b/2
@@ -1 +1 @@
-1.10.1
+1.11.0
--- a/changelog.json
+++ b/changelog.json
@@ -1,5 +1,23 @@
 {
  "versions": [
    {
      "version": "1.11.0",
      "date": "2026-06-02",
      "changes": {
        "features": [],
        "improvements": [
          "CCS811: passage d'un timer oneshot (10s) à un DAEMON long-running (nebuleair-ccs811-data.service, Type=simple, Restart=always). Le CCS811 doit être initialisé une seule fois puis lu en continu : chaque ré-init produit du garbage les premières secondes (eCO2=0 ou 0x8000=32768) et un reset toutes les 10s empêche la baseline de se construire. Nouveau CCS811/daemon.py (init 1x, boucle lecture/écriture 10s, re-init auto après erreurs I2C). write_data.py supprimé. setup_services.sh self-heal: supprime l'ancien timer .timer des capteurs en 1.10.x.",
          "CCS811/get_data.py (bouton Get Data) ne lit plus le capteur mais la dernière ligne de data_CCS811 — sinon collision I2C avec le daemon (= corruption observée sur pro100)."
        ],
        "fixes": [
          "CCS811: filtrage corrigé. La plage valide est [400, 8192] ppm; l'ancien filtre eCO2<400 laissait passer les valeurs corrompues 32768 (clock-stretching). Désormais tout échantillon hors plage est jeté."
        ],
        "compatibility": [
          "⚠ MATÉRIEL: sur Raspberry Pi le CCS811 exige de ralentir le bus I2C à 10 kHz (dtparam=i2c_arm_baudrate=10000 dans /boot/firmware/config.txt + reboot). Confirmé indispensable sur pro100: à 100 kHz, valeurs corrompues 32768 intermittentes. Réglage hors repo, à poser manuellement sur chaque capteur équipé d'un CCS811. BME280/RTC tolèrent 10 kHz."
        ]
      },
      "notes": "Daemon vérifié sur nebuleair-pro100 après reboot avec I2C à 10 kHz. Rappel burn-in CCS811: ~20 min de warm-up, ~48h de conditionnement initial. get_data.py renvoie maintenant aussi un champ timestamp (ignoré par sensors.html)."
    },
    {
      "version": "1.10.1",
      "date": "2026-06-02",
--- a/html/launcher.php
+++ b/html/launcher.php
@@ -1681,9 +1681,10 @@ if ($type == "get_systemd_services") {
                'description' => 'Reads CO2 concentration from MH-Z19 sensor',
                'frequency' => 'Every 2 minutes'
            ],
-            'nebuleair-ccs811-data.timer' => [
+            'nebuleair-ccs811-data.service' => [
-                'description' => 'Reads eCO2/TVOC from CCS811 air-quality sensor',
+                'display_name' => 'CCS811',
-                'frequency' => 'Every 10 seconds'
+                'description' => 'Reads TVOC/eCO2 from CCS811 air-quality sensor (daemon)',
                'frequency' => 'Continuous (daemon)'
            ],
            'nebuleair-s88-data.timer' => [
                'description' => 'Reads CO2 concentration from Senseair S88 sensor',
@@ -1776,7 +1777,7 @@ if ($type == "restart_systemd_service") {
        'nebuleair-noise-data.timer',
        'nebuleair-mhz19-data.timer',
        'nebuleair-s88-data.timer',
-        'nebuleair-ccs811-data.timer',
+        'nebuleair-ccs811-data.service',
        'nebuleair-db-cleanup-data.timer',
        'nebuleair-wifi-powersave.timer',
        'nebuleair-cpu-power.service',
@@ -1843,7 +1844,7 @@ if ($type == "toggle_systemd_service") {
        'nebuleair-noise-data.timer',
        'nebuleair-mhz19-data.timer',
        'nebuleair-s88-data.timer',
-        'nebuleair-ccs811-data.timer',
+        'nebuleair-ccs811-data.service',
        'nebuleair-db-cleanup-data.timer',
        'nebuleair-wifi-powersave.timer',
        'nebuleair-cpu-power.service',
--- a/services/setup_services.sh
+++ b/services/setup_services.sh
@@ -269,15 +269,19 @@ AccuracySec=1s
 WantedBy=timers.target
 EOL
-# Create service and timer files for CCS811 air-quality (eCO2/TVOC) Data
+# CCS811 air-quality (eCO2/TVOC) — long-running DAEMON, not a oneshot timer.
 # The CCS811 must be initialised once and read continuously (a 10s reset cycle
 # yields garbage right after each init and never lets its baseline build up).
 cat > /etc/systemd/system/nebuleair-ccs811-data.service << 'EOL'
 [Unit]
-Description=NebuleAir CCS811 Air-Quality (eCO2/TVOC) Data Collection Service
+Description=NebuleAir CCS811 Air-Quality (eCO2/TVOC) Daemon
 After=network.target
 [Service]
-Type=oneshot
+Type=simple
-ExecStart=/usr/bin/python3 /var/www/nebuleair_pro_4g/CCS811/write_data.py
+ExecStart=/usr/bin/python3 /var/www/nebuleair_pro_4g/CCS811/daemon.py
 Restart=always
 RestartSec=10
 User=root
 WorkingDirectory=/var/www/nebuleair_pro_4g
 StandardOutput=append:/var/www/nebuleair_pro_4g/logs/ccs811_service.log
@@ -287,19 +291,13 @@ StandardError=append:/var/www/nebuleair_pro_4g/logs/ccs811_service_errors.log
 WantedBy=multi-user.target
 EOL
-cat > /etc/systemd/system/nebuleair-ccs811-data.timer << 'EOL'
+# Self-heal: remove the obsolete oneshot timer from CCS811 v1.10.x (now a daemon).
-[Unit]
+if [ -f /etc/systemd/system/nebuleair-ccs811-data.timer ]; then
-Description=Run NebuleAir CCS811 Air-Quality Data Collection every 10 seconds
+    systemctl stop nebuleair-ccs811-data.timer 2>/dev/null
-Requires=nebuleair-ccs811-data.service
+    systemctl disable nebuleair-ccs811-data.timer 2>/dev/null
-
+    rm -f /etc/systemd/system/nebuleair-ccs811-data.timer
-[Timer]
+    echo "Removed obsolete nebuleair-ccs811-data.timer (CCS811 is now a daemon)"
-OnBootSec=10s
+fi
 OnUnitActiveSec=10s
 AccuracySec=1s
 [Install]
 WantedBy=timers.target
 EOL
 # Create service and timer files for Database Cleanup
 cat > /etc/systemd/system/nebuleair-db-cleanup-data.service << 'EOL'
@@ -434,12 +432,18 @@ systemctl daemon-reload
 # Enable and start all timers
 echo "Enabling and starting all services..."
-for service in npm envea sara bme280 mppt mhz19 s88 ccs811 db-cleanup noise; do
+for service in npm envea sara bme280 mppt mhz19 s88 db-cleanup noise; do
    systemctl enable nebuleair-$service-data.timer
    systemctl start nebuleair-$service-data.timer
    echo "Started nebuleair-$service-data timer"
 done
 # CCS811 is a long-running daemon (service, not timer)
 systemctl daemon-reload
 systemctl enable nebuleair-ccs811-data.service
 systemctl restart nebuleair-ccs811-data.service
 echo "Started nebuleair-ccs811-data service (daemon)"
 # Enable and start WiFi power save timer (separate naming convention)
 systemctl enable nebuleair-wifi-powersave.timer
 systemctl start nebuleair-wifi-powersave.timer
--- a/update_firmware.sh
+++ b/update_firmware.sh
@@ -232,6 +232,7 @@ services=(
    "nebuleair-mppt-data.timer"
    "nebuleair-noise-data.timer"
    "nebuleair-wifi-powersave.timer"
    "nebuleair-ccs811-data.service"
 )
 for service in "${services[@]}"; do