201109707 六、發明說明: 【發明所屬之技術領域】 訊的 /本發明係關於-種天氣資訊通報系統及其方法 係關於可提供使用者更立即地獲得區域性之即時天言’ 天氣資訊通報系統及其方法。 ;、° 【先前技術】 隨著科技的發展,近年來由於資訊產業發展迅速,言 二使:者可以隨身攜帶著電子#訊裝置。例如筆記㈣ 細、個人數位助理(PDA)或者是市面上常見的手 然要能讓使用者隨時隨地能攜帶在身上,因此, 二 =體大=最基本的條件’也就是重料 &上當電子資訊裝置變得人人可隨身攜帶後,接 1 讓使用者隨報地利用電子資訊裝置麵發各種不同的 =讯。而受到無線網路慢慢的普及,因此每個人 來取得各種不同的資訊。比如說,利用手機來觀 、士 ,電視頻道,或是利用手機上網瀏覽當曰的新聞等。 =也能讓有些使用者在臨時需要快速取得某方面的 夺’馬上能查詢得到。 口 ❹舉例而言,當使用者外出辦公或是出外郊遊時,若要 取得天氣資訊即可馬上利用手機上網即時劉覽,就可以立 ^的知道天氣情況。但是,利用手機上網所取得的天氣狀 /,大多是由氣象局提供。氣象局只提供某個縣市的天氣 201109707 疋數個固定景點的即時天氣資訊 。但是,有些正在 的天卜用者會想要取得附近區域或是即將前往之區域 話,可預先得知即將前往的區域正在下雨的 、可以先準備好雨具,以防被雨淋溼。 ,而’目魏象局無法提供更祕賴天氣資訊,並 所提供的天氣資訊不具有立即性。此外,有些使 、'w又有夕餘的時間去執行查詢天氣資訊的動作。對這 ^使用者來說’要特職時間上網查詢天氣資訊,是不方 便且沒有效率的。 【發明内容】 、本發=之一範疇係揭露一種天氣資訊通報系統,其係用 以發送天氣資訊至行動通訊裝置。本發明之天氣資訊通報 系統包含偵測模組以及第—基地台。偵測模組用以產生關 於一地區之一天氣特徵之偵測數據。第一基地台耦接至偵 測模組,用以接收偵測數據,根據偵測數據產生天氣資 汛,並發送天氣資訊至行動通訊裝置’例如無線廣播。因 此’本發明之天氣資訊通報系統可通報使用者第一基地台所 屬之地區之天氣資訊。 進一步地’當天氣資訊通報系統實施包含一通訊網路 中’而行動通訊裝置位於異於第一基地台之第二基地台的通 訊範圍内時’第一基地台仍可透過第二基地台以無線廣播 的方式發送該氣資訊至該動通訊裝置,進而實現遠端通報 的功能。此遠端通報功能除可擴大通報範圍(相對於行動 通訊裝置而言),增加(行動通訊裝置之)使用者反應時間 201109707 外’對於由k小涵蓋面積之基地台組成之通訊網路(例如 蜂巢式行動電話系統’直徑可能僅有約數公里),更具通 報實益。 此外’本發明之另一範疇係揭露一種天氣資訊通報方 法’其係用以由基地台發送天氣資訊至行動通訊裝置。本 發明之天氣資訊通報方法包含下列步驟。首先執行步驟 (a):以偵測模組產生關於一地區之一天氣特徵之偵測數 據。接者’執行步驟(b):以第一基地台接收偵測數據並 根據偵測數據產生天氣資訊。最後,執行步驟(c):以第 一基地台發送天氣資訊至行動通訊裝置。 同樣地’當本發明之天氣資訊通報方法實施於一通訊 、两路中’且通訊網路包含第一基地台及第二基地台時,即使 订動通訊裂置位於異於第一基地台之第二基地台的通訊範圍 内時’於步驗(c)中’第一基地台仍可透過第二基地台以無 線廣播的方式發送該氣資訊至該動通訊裝置,進而實現遠 端通報的功能。 έ ~上所述,相較於習知技術,本發明之天氣資訊通報系 ,及其方法可提供使用者更立即地獲得區域性的即時天氣 人4 ’進而使得使用者能預先掌握即將要前往之區域(包 =不同通訊細胞之區域)的天氣情況,且提早採取適當的 準備措施》 關於本發明之優點與精神可以藉由以下的發明詳述及 所附圖式得到進-步的瞭解。 201109707 【實施方式】 請參閱圖一。圖一係繪示根據本發明之一具體實施例 之天氣資訊通報系統3的系統方塊圖。如圖—所示,本發 明之天氣 > 訊通報系統3包含偵測模組32以及第一基地 台34。偵測模組32係用以產生關於偵測模組%所^地 區之天,特徵之偵測數據D1。此天氣特徵可包含該地區 之降雨量(包含累積雨量及降雨強度)、降雨的pH值、風 速、風向、氣溫(包含溫度及溼度)、空氣中有害氣體含量 (1 列如^、(^、^、叫等等谈其他可提供使用者參 ^之項_如其他光污·體含量、(沙塵爆之)懸浮微粒 密度),此將視偵測模組32配備之測量儀器而定。因此, 偵測數據DU字依制模组32侧對象(即前述天氣特徵) 的不同而可包含累積雨量(_、降雨強度(mm/hr)、pH 值、co2 含量(ppm)、co 含量(ppm)、風速(m/sec)、風 向、溫度rc或κ)、溼度等等。 第一基地台34耦接至偵測模組;32,用以接收偵測數 巧D1並根據偵測數據m產生天氣資訊。特別地,侦測 模組32可以是藉由導線與第一基地台34相連接,以便傳 送偵測數據D1給基地台。而偵測模組32亦可以是利用 無線傳輸的方式,將偵測數據D1傳送至第一基地台34。 此外,第一基地台34可以定義出訊號發送區域A1。 一立請參閱圖二A,圖二A係繪示圖一中之偵測模組32的 示意圖。如圖二A所示,於此具體實施例中,偵測模組 32可進一步包含漏斗321、容器322、電子量測器323以 201109707 大電量323之量測懸臂324。其中,漏斗 Γ 小開口處,雨水係可以由大開口處流 S St 容器322中。漏斗321可增加容器 此,或魏具有物4之_的速率,因 32卜雷tl i 具有漏斗狀的開口,即可省略漏斗 使η 323係經由量測懸臂324與容器322連接, 於半空中,電子量測器奶也同時_至 36虚接其t,二下將對侧模、组32 _乍以及行動通訊裳置 /、土也口 34之間的互動,分別 細莫組32的運作進行詳細的說明如下丁;先針對 321 m說又设天空開始下起雨時,雨水會經由漏斗 而旦、m, ^口:11·入’並經由小開σ處集中流出至容器322。 而里測懸臂似連接於電子量·奶 324原本可呈現水平狀態:當如二; 熊因Γ 322的重量變重,則量測懸臂324即破壞水 端向的容器322那 位移變化,進二=323會根據量測懸臂汹的 電子量測器323可以從量測懸臂32 ^得^許多資訊。舉例如下’當量測懸臂324 ^ = =r 323即可記錄現在—^ 電子量測器323可以從量測懸臂324位移變化的快慢, 201109707 即計算出目前的降聽率,而降雨速轉可判讀成為雨 小(降雨速率躲,代表雨勢愈大。反之,代表雨勢較小)。 而容器322可進一步被電子量測器323所控制。當雨旦 在容器322内累積到一定程度(例如:2〇毫米),電子^ 器323就輸出控制訊號給容器322,則容器322就開始放 容器322内的雨水(例如於容n 322底部設置電子閱門。)。合 釋放完-次雨水後,電子量測器323會記錄一次。若容^ 322又累積雨量至20毫米後,則再進行釋放。周而復始地了 電子3:測器323會持續地記錄所釋放雨水的次數。最後,把 ,放雨水的次絲上20絲後,即可以制這舰域的降雨 量。 上述各種資料數據都是經由量測懸臂324的位移變化, 並利用電子量測器323進行運算處理得到。這些資訊可再經 由電子量測器323重新整理成為侧數據m傳送給第 地台34。 特別地,細模組32不特別限定於本實施例的結構。舉 例來說’凊參晒二B。圖二B係!會示根據本發明之另一 具體實施例之制模組32,的示意圖。如圖二3所示,侦測 模組32’可包含浮力球321'、容器322,以及電子量測器323,。 而浮力球321連接至電子量測器323,。電子量測器%玲接 至第-基地台34 (電子量測器323,搞接至第一基地台%的 方式’可以是料線,亦可以是無線傳輸)。#下瞒,雨水 會累積至容器322’中。而浮力球奶,會因為雨水的累積而浮 起’進而產生位移變化。此時,電子量測㈣323,則可以經由 201109707 汗·力球321’的位移變化來取得許多關於雨水的資料。其取得 ^方式大體上都與上述的方法齡,故不再鱗贅述。請注 思二伯測她32㈣構並不以上述的實補為限,只要是能 取得雨水_資訊的方法都可翻於本發日狀天氣資訊通報 補充說明的是,由於電子量測器323,(或323)不以與第一 土地口 34有實體連接為限,故侧模組犯(或切亦不以設 置於第基地台34旁為限,偵測模組32,(或 可視f求而定(例如C〇2含量之侧點應、] 域而非如基地台多設置於高處)。 旱輛通他 動關::=r34以及行動通訊裝置36之間的互 管ί圖^示’當行動通訊裝置36進入第一基地台%之 祕域A1㈣,行動通訊裝置%向第— :錄以建立與第-基地台34之網路連接關係,藉此土 口 口 34可將根據接收到的偵測數據〇 曰二, ==:=36。此二: (包含行動通訊裝°置' 36)發&送資訊 9 . 發送天:行動為回 又或可第-基地台34接收行動通絲置36^«置36, 以向偵測触%發㈣_麟D ^之睛求後 生天氣資訊並發送;又或可第-基地台3Γί:後再產 的偵測數據超出預設範圍(例如風速 二其接收 疋逮度、溫度 201109707 過高(超過40°〇或過低(低於8°C)、降雨強度過強(大於 100mm/hr)、CO含量過高等等)時,第一基地台34自動發 送天氣資訊至行動通訊裝置36,而平時則可待行動通訊 裝置36發出請求再發送天氣資訊。 進一步地,當行動通訊裝置36包含GPS模組,且天 氣資訊包含關於第一基地台34或偵測模組32之地區座標 時,行動通訊裝置36的GPS模組可產生關於行動通訊裝 置36之定位座標並根據定位座標及接收的天氣資訊之地 區座標,於其顯示幕上顯示關於地區(偵測地點)之相對地 φ 理位置資訊,藉此(行動通訊裝置36的)使用者可明確得 知偵測地點相對位置(包含方向及距離),更能增加天氣資 訊對使用者的有效性。 請參閱圖一及圖三。圖三係繪示根據本發明之另一具 體實施例之天氣資訊通報系統3,的系統方塊圖。與圖一之 天氣貢訊通報系統3不同的是,圖三之天氣資訊通報系統3ι 包含一蜂巢式通訊網路,其包含第一基地台34、第二基地台 38及其他基地台(未標示)。當行動通訊裝置%未位於第一基籲 地台34之訊號發送區域人丨内時,第一基地台%仍得透過 第二基地台38以無線廣播的方式發送天氣資訊至行動通 訊裝置36(此時,行動通訊褒£ % #然位於第二基地台 3/,訊號發送區域A2,不待贅述)。其中第—基地台%與 第二基地台38間之通訊(即蜂巢式通訊網路)則屬習知技 術’不再贅述。於應用上,行動通訊裝置36可先向第二 基地台38發出對特定地區之天氣資訊之請求。第二基地 台38解析此請求以傳送此請求至第一基地台%,亦即第 201109707 二基地台38解析出前述特定地區係位於第一基地台%。 第一基地台34即據之以接收偵則數據D1並產生天氣資 訊,此天氣資訊接著被傳送至第二基地台38並再以無線 廣播的方式發送至行動通訊裝置36。藉此,本發明之天 氣資訊通報系統可達到遠端天氣資訊查詢的功能。 請參閱圖四。圖四係繪示根據本發明之一具體實施例 之天氣資訊通報方法的步驟流程圖。本發明之天氣資訊通 報方法係實施於本發明之天氣資訊通報系統。以圖一之天 氣資訊通報系統3為例,併參閱前述關於天氣資訊通報系 統3之說明’圖四之天氣資訊通報方法包含下列步驟: 首先’使用者所持之行動通訊裝置36進入第一基地 台34之訊號發送區域A1後’即向第一基地台34登錄以 取得與第一基地台34網路上的連接,如步驟S102所示。 接著’藉由行動通訊裝置36向第一基地台34發出請求以 獲什天氣資訊’如步驟S1 〇4所示。第一基地台34接收此 請求後,回應此請求以發送天氣資訊至行動通訊裝置 36(例如無線廣播),如步驟S106所示。 補充說明的是,配合不同的實施設計,第一基地台 34於接收此請求後可有不同的作動。例如,第一基地台 34於接收此請求後’始觸發偵測模組32以產生偵測數據 並發送至第一基地台34,第一基地台34再根據接收的偵 測數據產生天氣資訊,最後發送天氣資訊至行動通訊裝置 36。又例如,第一基地台34獨立運作以接收來自偵測模 組32之偵測數據’例如定時接收,待第一基地台34接收 11 201109707 到來自行動通訊裝置36之請求後,再根據最新的偵測數 據產生天氣資訊並發送出去。又例如,第一基地台34可 事先根據定時接收之偵測數據產生天氣資訊,以即時回應 行動通訊裝置36。 如步驟S108所示,行動通訊裝置36接收發送自第一 基地台34之天氣資訊並顯示天氣資訊於螢幕上。當行動 通訊裝置36包含GPS模組,並且天氣資訊包含關於第一 基地台34(或偵測模組32)之地區座標時,行動通訊裴置 36於接收天氣資訊後,可將Gps模組產生關於行動通訊 裝置36之定位座標與天氣資訊内之地區座標比較而顯示 關於第一基地台34(或偵測模組32)所在地區之相對地理 位置資訊。此相對地理位置資訊可包含方向及距離。藉 此,使用者可更有效、正確地、及時地運用接收的天氣資 訊。 再補充說明的是,圖四之流程圖雖需行動通訊裴置 6向第一基地台34發出請求為前提,但本發明不以此為 % I換句5舌說,天氣資訊的發送亦可無需行動通訊裴置 例如2請求,第一基地台34 #可逕行發送天氣資訊。 卜 基地台34定時向其訊號發送區域A1内所有的 置(包含行動通訊裝置36)發送天氣資訊;又例 (可泉、〜基地台34判斷其接收的偵測數據超出預設範圍 自‘私、、'』过說明,在此不再贅述)時,第一基地台34即 只送天氣資訊至行動通訊裝置36。 °月參閱圖五。圖五係繪示根據本發明之另一具體實施 12 201109707 以圖三之天氣資訊 統3之 例之天氣資訊通報方法的步驟流 通報系統3,為例,併參閱前述關於二°_=圖三之; 說明,圖五之天氣資訊通報方法包含報系、 首先,使用者所持之行動通訊掌 . 台38之訊號發送區域八2後,㈣\ 6進$二基地 取得與第二基地台38網路上的連一暴地台38登錄以 接著,藉由行動通訊裝置36向第_如步驟S3〇2所示。 地區之天氣資訊之請求,如步驟^4地台_38發出對特定 38接收此請求後,解析出前述特^ 台34,並傳送此請求至第—基地台3 :第一基= 36時’可能增加其他通訊必要 的要求),此制習知技術,不再贅述。通縣疋本身 再^著,第-基地台34 _應此請求赠天氣資訊 至第-基地台38 ’並由第二基地台38以無線廣播的方式 發送至行動通訊裝置36,如步驟S308所示。關於第一基 地台34根據接收自偵測模組32之偵測數據以產生天氣資 訊的方式可參閱前述各實施例,在此不再贅述。 行動通訊裝置36接收天氣資訊後,便顯示天氣資訊 於螢幕上,如步驟S310所示。同理,當行動通訊裝置36 具有GPS模組’且天氣資訊包含第一基地台34(或偵測模 組32)之地區座標時,行動通訊裝置36可一併顯示關於 第一基地台34(或偵測模組32)所在地區之相對地理位置 資訊。藉此,天氣資訊通報系統3,可實現遠端通報的功 13 201109707 能’進而使得使用者能預先掌握即將要前往之區域(包含 不同通訊細胞之區域)的天氣情況,且提早採取適當的準 備措施。相較於習知技術,本發明之天氣資訊通報系統及 其方法可提供使用者更立即地獲得區域性的即時天氣資 訊’進而使得使用者能預先掌握即將要前往之區域的天氣 情況’且提早採取適當的準備措施。 藉由以上較佳具體實施例之詳述,係希望能更加清楚 描述本發明之特徵與精神’而並非以上述所揭露的較佳具 體實施例來對本發明之範轉加以限制。相反地,其目的是_ 希望能涵蓋各種改變及具相等性的安排於本發明所欲申請 之專利範圍的範疇内。 【圖式簡單說明】 圖一係繪示根據本發明之一具體實施例之天氣資訊通 報系統的系統方塊圖。 圖二A係繪示圖一中之偵測模組的示意圖。 圖二B係繪示根據本發明之另一具體實施例之偵測模 組的示意圖。 圖三係繪示根據本發明之另一具體實施例之天氣資訊通 報系統的系統方塊圖。 圖四係繪示根據本發明之一具體實施例之天氣資訊通 報方法的步驟流程圖。 圖五係繪示根據本發明之另一具體實施例之天氣資訊 14 201109707 通報方法的步驟流程圖。 【主要元件符號說明】 3、3':天氣資訊通報系統 32 :偵測模組 34 :第一基地台 36 :行動通訊裝置 38 :第二基地台 _ 321 :漏斗 32Γ :浮力球 322、322':容器 323、323':電子量測器 324 :量測懸臂 A卜A2 :訊號發送區域 D1 :偵測數據 流程步驟:S102〜S108、S302〜S310 15201109707 VI. Description of the invention: [Technical field to which the invention pertains] The present invention relates to a weather information notification system and a method thereof for providing a user with a more immediate access to a regional instant weather message 'weather information notification system And its method. ;, ° [Previous technology] With the development of science and technology, in recent years, due to the rapid development of the information industry, the second two: people can carry electronic devices. For example, notes (4), personal digital assistants (PDAs) or common hands on the market should be able to allow users to carry them anywhere, anytime, so the second = body size = the most basic conditions - that is, heavy materials & After the electronic information device has been carried around, the user can use the electronic information device to send various different messages. And the wireless network is slowly spreading, so everyone gets a variety of different information. For example, use a mobile phone to watch TV, TV channels, or use your mobile phone to browse the news of Dangdang. = It also allows some users to quickly get some information in the temporary situation. For example, when a user goes out to work or go out for an outing, if you want to get weather information, you can use your mobile phone to access the instant browsing, and you can know the weather. However, the weather conditions obtained by using mobile phones to access the Internet are mostly provided by the Weather Bureau. The Weather Bureau only provides weather for a certain county and city. 201109707 Instant weather information for several fixed spots. However, some of the current Tianbo users will want to get the nearby area or the area to be visited. It is known in advance that the area to be visited is raining. You can prepare the rain gear first to prevent it from getting wet. However, the Bureau of Weixiang cannot provide more confidential weather information, and the weather information provided is not immediate. In addition, some of them let 'w have time to perform the action of querying weather information. It is inconvenient and inefficient for the user to use the special time to check the weather information online. SUMMARY OF THE INVENTION One aspect of the present invention is a weather information notification system for transmitting weather information to a mobile communication device. The weather information notification system of the present invention comprises a detection module and a first base station. The detection module is configured to generate detection data relating to weather features of one of the regions. The first base station is coupled to the detection module for receiving detection data, generating weather information based on the detected data, and transmitting weather information to the mobile communication device, such as a wireless broadcast. Therefore, the weather information notification system of the present invention can notify the user of the weather information of the area in which the first base station belongs. Further, when the weather information notification system is implemented in a communication network and the mobile communication device is located in the communication range of the second base station different from the first base station, the first base station can still wirelessly through the second base station. The method of broadcasting sends the gas information to the mobile communication device, thereby implementing the function of remote notification. In addition to expanding the scope of notification (relative to mobile communication devices), this remote notification function increases the user response time (mobile communication device) 201109707. 'For a communication network composed of base stations with a small coverage area (such as a honeycomb) The mobile phone system 'diameter may only be a few kilometers away) is more informative. Further, another aspect of the present invention discloses a weather information notification method for transmitting weather information from a base station to a mobile communication device. The weather information notification method of the present invention comprises the following steps. First, step (a) is performed: the detection module generates detection data about weather features of one of the regions. The receiver performs step (b): receiving the detection data by the first base station and generating weather information based on the detected data. Finally, step (c) is performed: the weather information is sent to the mobile communication device by the first base station. Similarly, when the weather information notification method of the present invention is implemented in a communication, two-way, and the communication network includes the first base station and the second base station, even if the subscription communication is located different from the first base station In the communication range of the two base stations, in the step (c), the first base station can still transmit the air information to the mobile communication device through the second base station by means of wireless broadcasting, thereby realizing the function of remote notification. . As described above, the weather information notification system of the present invention and the method thereof can provide a user to obtain a regional instant weather person 4' more immediately, thereby enabling the user to grasp in advance The weather conditions of the area (package = area of different communication cells), and appropriate preparation measures are taken early. The advantages and spirit of the present invention can be further understood by the following detailed description of the invention and the accompanying drawings. 201109707 [Embodiment] Please refer to Figure 1. 1 is a system block diagram of a weather information notification system 3 in accordance with an embodiment of the present invention. As shown in the figure, the weather > notification system 3 of the present invention includes a detection module 32 and a first base station 34. The detection module 32 is configured to generate the detection data D1 of the feature of the detection module %. This weather feature can include rainfall (including cumulative rainfall and rainfall intensity), rainfall pH, wind speed, wind direction, temperature (including temperature and humidity), and harmful air content in the air (1 column such as ^, (^, ^, call, etc. to other items that can provide user information _ such as other light and dirt content, (dust dust density) particle density, which will depend on the measuring instrument equipped with the detection module 32. Therefore, the detection data DU word may include accumulated rainfall (_, rainfall intensity (mm/hr), pH value, co2 content (ppm), co content depending on the side object of the module 32 (ie, the aforementioned weather characteristics) ( Ppm), wind speed (m/sec), wind direction, temperature rc or κ), humidity, etc. The first base station 34 is coupled to the detection module; 32, for receiving the detection data D1 and according to the detection data In particular, the detection module 32 can be connected to the first base station 34 by wires to transmit the detection data D1 to the base station. The detection module 32 can also be wirelessly transmitted. In a manner, the detection data D1 is transmitted to the first base station 34. In addition, the first base station 34 can be configured. The signal transmission area A1 is shown in Fig. 2A, and Fig. 2A is a schematic diagram of the detection module 32 in Fig. 1. As shown in Fig. 2A, in the specific embodiment, the detection mode is used. The group 32 can further include a funnel 321, a container 322, and an electronic measuring device 323 measuring the cantilever 324 with a large amount of electricity 323 at 201109707. wherein the funnel has a small opening, the rainwater can flow from the large opening into the S St container 322. 321 can increase the rate of the container, or the velocity of the material 4, because the 32 blei t1 has a funnel-shaped opening, the funnel can be omitted, and the η 323 is connected to the container 322 via the measuring cantilever 324, in midair, The electronic measuring device milk is also _ to 36 virtual connected to its t, the second will be the side mode, the group 32 _ 乍 and the interaction between the mobile communication skirt /, the earth also mouth 34, respectively, the operation of the group 32 The detailed description is as follows: First, for 321 m, when the sky starts to rain, the rain will pass through the funnel and the m, ^ mouth: 11·in' and flow out to the container 322 through the small opening σ. The test cantilever is connected to the amount of electrons. Milk 324 can be in a horizontal state: when it is like two; When the weight of Γ 322 becomes heavier, the displacement of the cantilever 324, that is, the displacement of the container 322 which destroys the water end direction is measured, and the electronic measuring device 323 which measures the cantilever 323 according to the measurement can be obtained from the measuring cantilever 32 ^ For example, the following can be used to calculate the current rate of change of the cantilever 324, and the speed of the rain is calculated by the electronic measuring device 323. The transfer can be read as rainy (the rainfall rate hides, which means the rain is greater. On the contrary, it means the rain is smaller). The container 322 can be further controlled by the electronic measure 323. When rainwater accumulates to a certain extent in the container 322 (for example, 2 mm), the electronic device 323 outputs a control signal to the container 322, and the container 322 starts to put rainwater in the container 322 (for example, the bottom of the container 322) Electronic reading.). After the release of the rainwater, the electronic measuring device 323 records once. If the capacity of 322 is accumulated to 20 mm, then release. Repeatedly, the electronic 3: detector 323 continuously records the number of times the rainwater is released. Finally, after putting 20 filaments on the secondary thread of rainwater, the rainfall of the ship can be made. The above various data are obtained by measuring the displacement change of the cantilever 324 and performing arithmetic processing using the electronic measuring device 323. This information can be rearranged by the electronic measuring unit 323 into side data m and transmitted to the ground station 34. In particular, the thin module 32 is not particularly limited to the structure of the embodiment. For example, 凊 凊 晒 二 二 B. Figure 2B is a schematic view of a module 32 in accordance with another embodiment of the present invention. As shown in FIG. 2, the detection module 32' may include a buoyancy ball 321', a container 322, and an electronic measuring device 323. The buoyancy ball 321 is connected to the electronic measuring device 323. The electronic measuring device is connected to the first base station 34 (the electronic measuring device 323, the manner of engaging the first base station %) may be a feed line or a wireless transmission). #下瞒, rainwater will accumulate in the container 322'. The buoyancy ball milk will float due to the accumulation of rain, which will cause displacement changes. At this time, in the electronic measurement (4) 323, a lot of information about the rainwater can be obtained by the displacement change of the 201109707 sweat force ball 321'. The method of obtaining ^ is generally the same as the method method described above, so it is no longer described in scale. Please note that the 32 (four) structure is not limited to the above-mentioned actual compensation, as long as it can obtain rainwater _ information can be turned over in this issue of the daily weather information to add to the explanation, because the electronic measuring device 323 (or 323) is not limited to the physical connection with the first land port 34, so the side module is guilty (or is not set to be limited to the side of the base station 34, the detection module 32, (or visible f It is determined (for example, the side point of the C〇2 content should be, and the domain is not set to a high position as the base station). The dry vehicle passes through the other::=r34 and the communication device 36 is connected. ^ When the mobile communication device 36 enters the first base station % of the secret domain A1 (four), the mobile communication device % to the first -: recorded to establish a network connection relationship with the first base station 34, whereby the earth mouth mouth 34 can According to the received detection data 〇曰 two, ==:=36. These two: (including mobile communication installation ° '36) send & send information 9 . Send days: action for return or can be - base station 34 receiving action wire set 36 ^ « set 36, in order to detect the touch of the hair (four) _ Lin D ^ the eyes of the after-sales weather information and send; or can be - base station 3 Γ ί: after The detected data is out of the preset range (for example, wind speed 2, its receiving 疋 catch, temperature 201109707 is too high (over 40 ° 〇 or too low (below 8 ° C), excessive rainfall intensity (greater than 100 mm / hr), CO When the content is too high, etc., the first base station 34 automatically sends the weather information to the mobile communication device 36, and in the usual case, the mobile communication device 36 sends a request to send the weather information. Further, when the mobile communication device 36 includes the GPS module When the weather information includes the regional coordinates of the first base station 34 or the detection module 32, the GPS module of the mobile communication device 36 can generate the positioning coordinates of the mobile communication device 36 and according to the positioning coordinates and the received weather information. The regional coordinates display the relative location information of the area (detection location) on the display screen, so that the user (the mobile communication device 36) can clearly know the relative location of the detection location (including direction and distance). It is more effective to increase the effectiveness of the weather information to the user. Please refer to FIG. 1 and FIG. 3. FIG. 3 is a diagram showing a weather information notification system according to another embodiment of the present invention. 3, a system block diagram. Unlike the weather tribute notification system 3 of FIG. 1, the weather information notification system 3ι of FIG. 3 includes a cellular communication network including a first base station 34, a second base station 38, and Other base stations (not shown). When the mobile communication device % is not located in the signal transmission area of the first base station 34, the first base station % still has to be sent by wireless broadcast through the second base station 38. Weather information to the mobile communication device 36 (at this time, the mobile communication is only located in the second base station 3/, the signal transmission area A2, not to be described). The communication between the first base station % and the second base station 38 (ie, the cellular communication network) is a well-known technology 'will not be described again. In application, the mobile communication device 36 may first issue a request for weather information for a particular region to the second base station 38. The second base station 38 resolves the request to transmit the request to the first base station %, i.e., the 201109707 two base station 38 resolves that the particular area is located at the first base station %. The first base station 34 receives the statistic data D1 and generates weather information, which is then transmitted to the second base station 38 and transmitted to the mobile communication device 36 in a wireless broadcast. Thereby, the weather information notification system of the present invention can achieve the function of remote weather information inquiry. Please refer to Figure 4. Figure 4 is a flow chart showing the steps of a weather information notification method in accordance with an embodiment of the present invention. The weather information reporting method of the present invention is implemented in the weather information notification system of the present invention. Taking the weather information notification system 3 of FIG. 1 as an example, and referring to the foregoing description of the weather information notification system 3, the weather information notification method of FIG. 4 includes the following steps: First, the user's mobile communication device 36 enters the first base station. After the signal transmission area A1 of 34 is 'registered with the first base station 34 to obtain the connection with the first base station 34 network, as shown in step S102. Then, the request is sent to the first base station 34 by the mobile communication device 36 to obtain the weather information as shown in step S1 〇4. After receiving the request, the first base station 34 responds to the request to send weather information to the mobile communication device 36 (e.g., wireless broadcast) as shown in step S106. It is added that, in conjunction with different implementation designs, the first base station 34 may have different actions after receiving the request. For example, after receiving the request, the first base station 34 initially triggers the detection module 32 to generate detection data and sends the detection data to the first base station 34, and the first base station 34 generates weather information according to the received detection data. Finally, the weather information is sent to the mobile communication device 36. For another example, the first base station 34 operates independently to receive the detected data from the detection module 32, for example, timing reception, and after the first base station 34 receives 11 201109707 to the request from the mobile communication device 36, according to the latest The detection data generates weather information and sends it out. For another example, the first base station 34 may generate weather information based on the detected data received at a predetermined time to immediately respond to the mobile communication device 36. As shown in step S108, the mobile communication device 36 receives the weather information transmitted from the first base station 34 and displays the weather information on the screen. When the mobile communication device 36 includes a GPS module, and the weather information includes the regional coordinates of the first base station 34 (or the detection module 32), the mobile communication device 36 can generate the GPS module after receiving the weather information. The relative coordinates of the area of the first base station 34 (or the detection module 32) are displayed with respect to the location coordinates of the mobile communication device 36 compared to the regional coordinates within the weather information. This relative geographic location information can include directions and distances. In this way, users can use the received weather information more effectively, correctly and in a timely manner. It should be added that the flow chart of FIG. 4 requires the mobile communication device 6 to issue a request to the first base station 34, but the present invention does not use this as a % I sentence, and the weather information can also be sent. The first base station 34 # can send weather information without the need for a mobile communication device such as a 2 request. The base station 34 periodically sends weather information to all the devices (including the mobile communication device 36) in the signal transmission area A1; and the example (the spring, the base station 34 determines that the detected data received by the base station exceeds the preset range from the private The first base station 34 sends only weather information to the mobile communication device 36 when the description is not repeated here. See Figure 5 for the month. FIG. 5 is a diagram showing a flow notification system 3 according to another embodiment of the present invention, which is based on the weather information notification method of FIG. 3, for example, and refers to the foregoing regarding the second _= FIG. Note that the weather information notification method of Figure 5 includes the newspaper system, first of all, the user's mobile communication palm. The signal transmission area of the station 38 is after the 8th, (4) \ 6 input $ 2 base acquisition and the second base station 38 network The torrent platform 38 on the road is logged in, and then, by the mobile communication device 36, as shown in step S3 〇2. The request for the weather information of the area, such as step ^4, the platform _38 sends out the request to the specific 38, parses out the above-mentioned special station 34, and transmits the request to the first base station 3: the first base = 36 hours' It may increase the necessary requirements for other communications.) This technique is not repeated here. The Tongxian 疋 itself is again, the first base station 34 _ requests the weather information to the base station 38' and is sent by the second base station 38 to the mobile communication device 36 by way of wireless broadcasting, as in step S308. Show. For the manner in which the first base station 34 receives the detected data from the detection module 32 to generate the weather information, reference may be made to the foregoing embodiments, and details are not described herein again. After receiving the weather information, the mobile communication device 36 displays the weather information on the screen as shown in step S310. Similarly, when the mobile communication device 36 has a GPS module 'and the weather information includes the regional coordinates of the first base station 34 (or the detection module 32), the mobile communication device 36 can display the first base station 34 together ( Or the relative geographical location information of the area where the module 32) is detected. In this way, the weather information notification system 3 can realize the remote notification work 13 201109707 can further enable the user to grasp in advance the weather conditions of the area to be visited (the area containing different communication cells), and take appropriate preparations in advance. Measures. Compared with the prior art, the weather information notification system and method thereof of the present invention can provide users with more immediate access to regional real-time weather information 'and thus enable the user to grasp the weather conditions of the area to be visited in advance' and early Take appropriate preparation measures. The features and spirits of the present invention are intended to be more <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; On the contrary, the intention is to cover various modifications and equivalent arrangements within the scope of the invention as claimed. BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a system block diagram of a weather information reporting system in accordance with an embodiment of the present invention. Figure 2A is a schematic diagram of the detection module of Figure 1. Figure 2B is a schematic diagram showing a detection module in accordance with another embodiment of the present invention. Figure 3 is a block diagram showing the system of a weather information reporting system in accordance with another embodiment of the present invention. Figure 4 is a flow chart showing the steps of a weather information reporting method in accordance with an embodiment of the present invention. Figure 5 is a flow chart showing the steps of the notification method according to another embodiment of the weather information 14 201109707. [Main component symbol description] 3, 3': weather information notification system 32: detection module 34: first base station 36: mobile communication device 38: second base station _321: funnel 32 Γ: buoyancy ball 322, 322' : Container 323, 323': electronic measuring device 324: measuring cantilever A A2: signal transmitting area D1: detecting data flow steps: S102~S108, S302~S310 15