MXG模拟和矢量信号发生器技术指标

信号的技术参数信号是指在电信领域中所传递的信息，可以是声音、图像、数据或者其他形式的信息。

信号传输的质量对通讯系统的性能至关重要，因此信号的技术参数具有重要的意义。

下面将详细介绍信号的技术参数，包括信号的类型、频率、带宽、幅度等方面。

一、信号的类型根据传输方式和形式的不同，信号可以分为模拟信号和数字信号两种类型。

1. 模拟信号：模拟信号是连续变化的信号，它的数值是连续的，可以用连续的数学函数来表示。

模拟信号可以是声音、电压、电流等形式的信号。

2. 数字信号：数字信号是离散的信号，它是用数字表示的信号，采用离散的数学函数表示。

数字信号可以是文本、图像、视频等形式的信号。

二、频率1. 信号的频率是指信号每秒钟的周期性变化次数，单位是赫兹（Hz）。

频率决定了信号波形的快慢，影响信号的传输速度和传输距离。

2. 在无线通信中，频率范围分为低频、中频、高频和超高频等不同范围，不同频段的信号在传输性能和覆盖范围上有所差异。

三、带宽1. 信号的带宽是指信号频谱的宽度，它是从频谱中心向两侧延伸至减小到零的频率范围，通常用赫兹（Hz）来表示。

2. 带宽决定了信号所能携带的信息量，带宽越宽，信号携带的信息量越大，传输速度越快。

四、幅度1. 信号的幅度是指信号的振幅大小，也就是信号的高低或者是信号的强弱。

在模拟信号中，幅度可以用电压、电流等物理量来表示；在数字信号中，幅度可以用数字大小表示。

以上就是关于信号的技术参数的详细介绍，其中包括了信号的类型、频率、带宽、幅度等方面的内容。

这些技术参数对于通信系统的设计和优化具有重要的意义，也对信号传输的质量和性能有着重要的影响。

1445B通信矢量信号发生产品综述1445B通信矢量信号发生器作为一款通用的射频矢量信号源，频率范围覆盖100kHz～6GHz，具有优良的频谱纯度和功率输出指标；支持CW信号、模拟与数字调制信号、全制式的通信标准信号以及NB-IoT、WiFi和蓝牙信号发生功能，支持用户自定义基带数据信号发生。

1445B既是理想的本振源和时钟源，也是高性能的矢量信号源，优良的信号质量可进行物联网模组、基站和射频元器件的研发、生产与认证等，适用于教学实验、航空航天、移动通信、国防军工及雷达天线等众多领域。

主要特点⚫频率覆盖范围：100kHz～6GHz；⚫功率输出范围：-120 dBm～+20 dBm；⚫蜂窝网通信标准信号：NB-IoT/IoT-G/5G NR/TDD-LTE/FDD-LTE/TD-SCDMA/WCDMA/GSM/EDGE，为高质量移动通信物联网设备测试提供全面的解决手段；⚫非蜂窝网通信标准：WiFi802.11a/g/j/n/ac、蓝牙、LoRa；⚫丰富的数字调制格式：BPSK、QPSK、OQPSK、8PSK、16QAM、32QAM、64QAM、128QAM、256QAM等数字调制格式，用户可灵活配置不同调制方式及码元速率；⚫模拟调制功能：幅度调制、相位调制、频率调制、脉冲调制；⚫GPIB、LAN和USB等丰富程控接口，方便用户实现远程控制及网络升级。

基本功能数字调制数字调制是现代通信的重要方法，1445B可输出多种数字调制信号。

通信标准制式信号发生无线通信标准制式都具有标准的物理层结构，可根据标准产生各类标准制式信号。

NB-IoT标准信号发生5G NR标准信号发生LTE标准信号发生TD-SCDMA标准信号发生GSM标准信号发生物联网模块测试1445B可与5264B通信矢量信号分析仪组成物联网模组测试系统，支持WiFi、蓝牙和NB-IoT信号发生功能，可与物联网模组建立非信令连接，进行相应的射频测试及业务测试。

鍑犵寰尝淇″彿鍙戠敓鍣ㄩ€夋嫨姣旇緝淇″彿鍙戠敓鍣ㄤ俊鍙峰彂鐢熷櫒淇″彿鍙戠敓鍣ㄥ湪娴嬭瘯绯荤粺涓湁鏄庣‘瑙勫畾鐨勪换鍔★細妯℃嫙琚祴璁惧锛圖UT锛夊湪姝ｅ父宸ヤ綔鏃跺彲鑳介亣鍒扮殑淇″彿銆傝繖绉嶄俊鍙疯繃鍘诲彧鏄寮︽尝銆佽剦鍐叉垨缁忚繃妯℃嫙璋冨埗鐨勪俊鍙枫€備絾闅忕潃閫氫俊鏍煎紡涓嶆柇鍙戝睍鑰屼笉鍐嶅眬闄愪簬绠€鍗曠殑璋冨箙锛圓M锛夊拰璋冮锛團M锛夛紝瀵逛俊鍙峰彂鐢熷櫒鐨勮姹傛鍙樺緱瓒婃潵瓒婇珮銆傞殢鐫€瓒婃潵瓒婂鍦拌澶囦娇鐢ㄦ暟瀛楄皟鍒舵牸寮忥紙鍜岄潪浼犵粺鐨勪俊鍙锋牸寮忥紝濡傝烦棰戝拰瓒呭甯︼紙UWB锛夐€氫俊锛夛紝鏂扮殑淇″彿鍙戠敓鍣ㄥ繀椤昏兘澶熸ā鎷熼噰鐢ㄥ鏉傛暟瀛楄皟鍒舵柟妗堢殑澶氶淇″彿銆備笉浠呭姝わ紝淇″彿鍙戠敓鍣ㄧ殑澶栧舰涔熷湪鍙戠敓鍙樺寲锛屼粠浼犵粺鐨勬満鏋跺紡鎴栧彴寮忎华鍣ㄥ彂灞曞埌浜嗘洿绱у噾鐨勬ā鍧楋紝鍦ㄦ浘缁忔槸涓€鍙颁俊鍙峰彂鐢熷櫒鍗犵敤鐨勭┖闂村唴鐜板湪鍙互鎽嗘斁澶氬彴鍒嗙珛淇″彿婧愩€?銆€銆€浼犵粺鐨勬満鏋跺紡淇″彿鍙戠敓鍣ㄤ粛鐒跺湪鎵ц瀹冧滑浠藉唴鐨勬祴璇曚换鍔★紝鏈夋椂浣滀负鐙珛鐨勪华鍣紝鏈夋椂浣滀负鑷姩鍖栫郴缁熺殑涓€閮ㄥ垎锛岃€屽ぇ澶氭暟涓昏鐨勬祴璇曡澶囧埗閫犲晢閮借兘鎻愪緵绉嶇被绻佸鐨勫井娉俊鍙峰彂鐢熷櫒锛屽苟涓旈€氬父鎸夐鐜囪寖鍥存潵鍒嗙被銆傞€夋嫨涓€娆句俊鍙峰彂鐢熷櫒瑕佹眰鍖归厤浠櫒鐨勬€ц兘姘村钩鍜屽疄闄呭簲鐢ㄩ渶姹傦紝鑰岄鐜囪寖鍥淬€佽緭鍑哄姛鐜囥€侀鐜囧拰鐢靛钩鍒囨崲閫熷害浠ュ強棰戣氨绾害绛夊弬鏁伴€氬父鏄汉浠仛鍑哄悎鐞嗛€夋嫨鐨勫叧閿€?銆€銆€褰撶劧锛屾病鏈変竴鍙颁俊鍙峰彂鐢熷櫒鑳藉婊¤冻鎵€鏈夋祴璇曞簲鐢ㄧ殑闇€姹傦紝璇曞浘鎻愪緵瓒冲鐨勫甫瀹姐€佽緭鍑哄姛鐜囥€佽皟璋愰€熷害鍜岄璋辩函搴﹀彧浼氬鑷撮珮鏄傜殑銆佸彲鑳借秴杩囧ぇ澶氭暟锛堝鏋滀笉鏄叏閮級棰勭畻鐨勪环鏍笺€傚洜姝わ紝澶у鏁板晢鐢ㄧ殑淇″彿鍙戠敓鍣ㄥ湪閿€鍞椂浼氬垝鍒嗕负瀹藉甫銆侀€氱敤浠櫒锛堝10MHz鑷?8GHz锛夋垨“鐗瑰畾棰戝甫”浠櫒锛堣鐩栫敤鎴锋劅鍏磋叮鐨勭壒瀹氶鐜囷紝濡傜敤浜庡崼鏄熼€氫俊鍜岀數淇″簲鐢ㄧ殑3.7GHz鑷?.2GHz鍜?.9GHz鑷?.4GHz锛夈€傛湰鏂囧皢閲嶇偣璁ㄨ姣旇緝浼犵粺鐨勫甯︽祴璇曚俊鍙锋簮銆傚悗缁枃绔犲皢浠嬬粛鍏跺畠涓€浜涗俊鍙峰彂鐢熷櫒绫诲瀷锛屽寘鎷换鎰忔尝鍙戠敓鍣紙AWG锛夊拰鐭㈤噺淇″彿鍙戠敓鍣紙VSG锛夈€?銆€銆€鍦ㄧ涓€绫诲叿鏈夊璋冭皭鑼冨洿鐨勪俊鍙峰彂鐢熷櫒鍐咃紝Giga-tronics 鍏徃鐨?550B鍨嬩骇鍝侊紙鍥?锛変粎鍑竴鍙颁华鍣ㄥ拰涓€涓紙2.4mm锛夎繛鎺ュ櫒灏辫鐩栦簡2GHz鑷?0GHz鐨勯鐜囪寖鍥达紝骞朵笖閫氳繃涓€涓€夐」杩樺彲浠ユ妸棰戠巼鑼冨洿鎵╁睍鑷?0kHz銆?500B绯诲垪涓繕鏈夊叾瀹冧竴浜涗俊鍙峰彂鐢熷櫒锛屽垎鍒鐩?0kHz鑷?.5GHz銆?GHz鑷?GHz銆?GHz鑷?0GHz銆?GHz鑷?6.5GHz鍜?GHz鑷?0GHz 鐨勯鐜囪寖鍥达紝鎵€鏈夎繖浜涗俊鍙峰彂鐢熷櫒閮藉叿鏈?.001Hz鐨勯鐜囪皟璋愬垎杈ㄧ巼銆傝繖浜涗俊鍙峰彂鐢熷櫒鍙互鎻愪緵璁稿瀵瑰崼鏄熸祴璇曞簲鐢ㄦ潵璇存瀬鏈変环鍊肩殑鐗规€э紝鍖呮嫭澶ц緭鍑哄姛鐜囥€佽緝蹇殑鍒囨崲閫熷害鍜屼綆鐩镐綅鍣０銆傛爣閰嶄笅鐨勮緭鍑哄姛鐜囧湪20GHz浠ヤ笅瓒呰繃+20dBm锛岀ǔ瀹氬埌500MHz浠ヤ笅鐨勬柊棰戠巼鎵€闇€鐨勬椂闂翠笉鍒?50μs锛屽箙搴︾ǔ瀹氭椂闂翠笉鍒?00μs 銆?0GHz杞芥尝锛?kHz鍋忕Щ鏃剁殑鐩镐綅鍣０鏄?102dBc/Hz锛?0GHz杞芥尝锛?0kHz鍋忕Щ鏃剁殑鐩镐綅鍣０鏄?108dBc/Hz锛屽湪50GHz鑼冨洿鍐呰皭娉㈤€氬父灏忎簬-30dBc 锛屾潅鏁ｉ€氬父灏忎簬-50dBc銆?銆€銆€銆€銆€鍥?锛?550B鍨嬩俊鍙峰彂鐢熷櫒鍏锋湁瀹借皟璋愯寖鍥达紝鏍囧噯棰戠巼鑼冨洿鏄?GHz鑷?0GHz锛屽苟鍙墿灞曡嚦10kHz銆?銆€銆€鍦ㄤ簡瑙ｄ簡鏈夊叧棰戣氨绾害鐨勮繖浜涙寚鏍囧悗锛岃繕闇€瑕佹敞鎰忥紝鎬ц兘姘村钩鏄鐜囩殑鍑芥暟锛岀壒鍒槸鍦ㄦ瘮杈冧笉鍚屽埗閫犲晢鐨勪俊鍙峰彂鐢熷櫒鏃躲€備互2550B鍨嬩负渚嬶紝浠?00MHz鐩村埌39.6GHz鑼冨洿鍐呯殑璋愭尝閫氬父鏄?50dBc锛屽湪鏇撮珮鍜屾洿浣庨甯﹁皭娉㈡€ц兘鍒欒緝浣庛€傚悓鏍凤紝鍦ㄧ洿鍒?0.1GHz鐨勯鐜囪寖鍥村唴锛屾潅鏁ｆ€ц兘鍙揪-66dBc锛屽湪10.1GHz鑷?9.6GHz 鑼冨洿鍐呮潅鏁ｆ€ц兘鍙揪-54dBc銆傝繖浜涙€ц兘姘村钩涓嶄粎鏄熀棰戞尟鑽″櫒銆佸熀鍑嗘尟鑽″櫒銆佷骇鐢熶俊鍙峰彂鐢熷櫒寰尝棰戠巼鎵€鐢ㄧ殑棰戠巼鍚堟垚鏂规硶鐨勫嚱鏁帮紝鑰屼笖鏄骇鐢熸渶楂橀甯︽墍鐢ㄧ殑涔樻硶鏂规鐨勫嚱鏁般€?銆€銆€鍏跺畠瀹藉甫鍙板紡淇″彿鍙戠敓鍣ㄥ寘鎷畨鎹蜂鸡绉戞妧鍏徃锛圓gilent Technologies锛夌殑MXG鍜孭SG浠櫒銆丄nritsu鍏徃鐨凪G37000A绯诲垪淇″彿鍙戠敓鍣ㄥ拰缃楀痉涓庢柦鐡﹁尐鍏徃锛圧&S锛夌殑R&S SMF100A寰尝淇″彿鍙戠敓鍣ㄣ€傛墍鏈夎繖浜涗俊鍙峰彂鐢熷櫒閮藉寘鍚揪鍒版绫虫尝棰戠巼鐨勭増鏈紝骞跺叿鏈夊緢濂界殑杈撳嚭鍔熺巼鍜屼紭绉€鐨勯璋辩函搴︺€備緥濡傦紝MXG绯诲垪淇″彿鍙戠敓鍣ㄧ殑棰戠巼鑼冨洿涓?00kHz鑷?0GHz銆?1.8GHz鎴?0GHz锛屽苟涓旈兘鍏锋湁0.01Hz棰戠巼鍒嗚鲸鐜囥€?0GHz浠ヤ笅鐨勬爣鍑嗚緭鍑哄姛鐜囦负+11dBm锛?0GHz鑷?0GHz 鐨勬爣鍑嗚緭鍑哄姛鐜囦负+7dBm锛屽彟鏈夐€夐」鍙皢20GHz浠ヤ笅鐨勮緭鍑哄姛鐜囨彁鍗囪嚦+18dBm锛屽皢20GHz鑷?0GHz鑼冨洿鐨勮緭鍑哄姛鐜囨彁鍗囪嚦+12dBm銆?銆€銆€褰撳伐浣滃湪涓€绯诲垪缂栫▼棰戠巼锛堝垪琛ㄦā寮忥級鏃讹紝浣滀负琛￠噺鍒囨崲鍒扮壒瀹氬垎杈ㄧ巼鍐呯殑鏂伴鐜囨墍闇€鏃堕棿鐨勬寚鏍?mdash;—棰戠巼绋冲畾鏃堕棿鎴栧垏鎹㈤€熷害鍦?ms鎴?ms浠ヤ笅锛堝湪姣旇緝杩欎簺鏁板瓧鏃讹紝璁よ瘑鍒颁笉鍚屽埗閫犲晢鍙兘浣跨敤涓嶅悓鐨勭ǔ瀹氭椂闂村畾涔夊緢閲嶈锛夈€備綔涓轰竴涓彲閫夊姛鑳斤紝鍒囨崲閫熷害鍙互琚姞閫熷埌鍏稿瀷鐨?00μs銆備笌璁稿鍏稿瀷鐨勪俊鍙峰彂鐢熷櫒涓€鏍凤紝鏍囧噯閰嶇疆鏃剁殑杈撳嚭鐢靛钩鍙互闄嶄綆鑷崇害-20dBm锛屽埄鐢ㄩ€夐厤鐨勫唴閮ㄦ杩涜“鍑忓櫒杩樺彲浠ラ檷浣庡埌-90dBm銆傜浉浣嶅櫔澹板吀鍨嬪€兼槸-98dBc/Hz锛?GHz鎴?2GHz杞芥尝锛?0kHz鍋忕Щ锛夈€?0GHz浠ヤ笅鐨勮皭娉㈠吀鍨嬪€间负-60dBc锛?0GHz鑷?0GHz鐨勮皭娉㈠吀鍨嬪€间负-56dBc銆傝€?4GHz浠ヤ笅鐨勬潅鏁ｅ吀鍨嬪€间负-50dBc锛?4GHz鍒?0GHz鏃剁殑鏉傛暎鍏稿瀷鍊兼槸-45dBc銆侻XG淇″彿鍙戠敓鍣ㄦ嫢鏈夊ぇ閲忚皟鍒堕€夐」锛屽寘鎷皟骞咃紙AM锛夈€佽皟棰戯紙FM锛夈€佺浉浣嶈皟鍒跺拰鑴夊啿璋冨埗銆?銆€銆€E8257D鏄畨鎹蜂鸡PSG淇″彿鍙戠敓鍣ㄧ郴鍒椾骇鍝佷腑鐨勪竴绉嶏紝杩欎竴绯诲垪浜у搧鐨勯鐜囪寖鍥磋鐩栦粠250kHz鑷?0GHz銆?1.8GHz銆?0GHz鍜?7GHz锛屽苟涓旀墍鏈変骇鍝佸湪杩炵画娉紙CW锛夊伐浣滄ā寮忎笅鍏锋湁0.001Hz棰戠巼鍒嗚鲸鐜囷紝鍦ㄦ壂鎻忔垨鍒楄〃妯″紡涓嬪叿鏈?.01Hz鍒嗚鲸鐜囥€傛爣鍑嗛鐜囩ǔ瀹氭椂闂村皬浜?ms锛?0GHz浠ヤ笅鐨勪俊鍙疯緭鍑虹數骞宠揪+20dBm銆傚湪鏍囧噯鍨嬪彿浜у搧涓繖浜涜緭鍑哄姛鐜囧彲浠ラ檷浣庤嚦-20dBm锛屽湪甯﹀彲閫夋杩涜“鍑忓櫒鐨勪骇鍝佷腑杈撳嚭鍔熺巼鍙互闄嶄綆鍒?110鎴?135dBm銆傜浉浣嶅櫔澹板吀鍨嬪€间负-107dBc/Hz 锛?0GHz杞芥尝锛?kHz鍋忕Щ锛夛紝鑰?0GHz浠ヤ笅鐨勮皭娉负-55dBc锛?0GHz浠ヤ笅鐨勬潅鏁ｅ吀鍨嬪€间负-58dBc銆?銆€銆€淇″彿鍙戠敓鍣ㄥ湪娴嬭瘯绯荤粺涓湁鏄庣‘瑙勫畾鐨勪换鍔★細妯℃嫙琚祴璁惧锛圖UT锛夊湪姝ｅ父宸ヤ綔鏃跺彲鑳介亣鍒扮殑淇″彿銆傝繖绉嶄俊鍙疯繃鍘诲彧鏄寮︽尝銆佽剦鍐叉垨缁忚繃妯℃嫙璋冨埗鐨勪俊鍙枫€備絾闅忕潃閫氫俊鏍煎紡涓嶆柇鍙戝睍鑰屼笉鍐嶅眬闄愪簬绠€鍗曠殑璋冨箙锛圓M锛夊拰璋冮锛團M锛夛紝瀵逛俊鍙峰彂鐢熷櫒鐨勮姹傛鍙樺緱瓒婃潵瓒婇珮銆傞殢鐫€瓒婃潵瓒婂鍦拌澶囦娇鐢ㄦ暟瀛楄皟鍒舵牸寮忥紙鍜岄潪浼犵粺鐨勪俊鍙锋牸寮忥紝濡傝烦棰戝拰瓒呭甯︼紙UWB锛夐€氫俊锛夛紝鏂扮殑淇″彿鍙戠敓鍣ㄥ繀椤昏兘澶熸ā鎷熼噰鐢ㄥ鏉傛暟瀛楄皟鍒舵柟妗堢殑澶氶淇″彿銆備笉浠呭姝わ紝淇″彿鍙戠敓鍣ㄧ殑澶栧舰涔熷湪鍙戠敓鍙樺寲锛屼粠浼犵粺鐨勬満鏋跺紡鎴栧彴寮忎华鍣ㄥ彂灞曞埌浜嗘洿绱у噾鐨勬ā鍧楋紝鍦ㄦ浘缁忔槸涓€鍙颁俊鍙峰彂鐢熷櫒鍗犵敤鐨勭┖闂村唴鐜板湪鍙互鎽嗘斁澶氬彴鍒嗙珛淇″彿婧愩€?銆€銆€浼犵粺鐨勬満鏋跺紡淇″彿鍙戠敓鍣ㄤ粛鐒跺湪鎵ц瀹冧滑浠藉唴鐨勬祴璇曚换鍔★紝鏈夋椂浣滀负鐙珛鐨勪华鍣紝鏈夋椂浣滀负鑷姩鍖栫郴缁熺殑涓€閮ㄥ垎锛岃€屽ぇ澶氭暟涓昏鐨勬祴璇曡澶囧埗閫犲晢閮借兘鎻愪緵绉嶇被绻佸鐨勫井娉俊鍙峰彂鐢熷櫒锛屽苟涓旈€氬父鎸夐鐜囪寖鍥存潵鍒嗙被銆傞€夋嫨涓€娆句俊鍙峰彂鐢熷櫒瑕佹眰鍖归厤浠櫒鐨勬€ц兘姘村钩鍜屽疄闄呭簲鐢ㄩ渶姹傦紝鑰岄鐜囪寖鍥淬€佽緭鍑哄姛鐜囥€侀鐜囧拰鐢靛钩鍒囨崲閫熷害浠ュ強棰戣氨绾害绛夊弬鏁伴€氬父鏄汉浠仛鍑哄悎鐞嗛€夋嫨鐨勫叧閿€?銆€銆€褰撶劧锛屾病鏈変竴鍙颁俊鍙峰彂鐢熷櫒鑳藉婊¤冻鎵€鏈夋祴璇曞簲鐢ㄧ殑闇€姹傦紝璇曞浘鎻愪緵瓒冲鐨勫甫瀹姐€佽緭鍑哄姛鐜囥€佽皟璋愰€熷害鍜岄璋辩函搴﹀彧浼氬鑷撮珮鏄傜殑銆佸彲鑳借秴杩囧ぇ澶氭暟锛堝鏋滀笉鏄叏閮級棰勭畻鐨勪环鏍笺€傚洜姝わ紝澶у鏁板晢鐢ㄧ殑淇″彿鍙戠敓鍣ㄥ湪閿€鍞椂浼氬垝鍒嗕负瀹藉甫銆侀€氱敤浠櫒锛堝10MHz鑷?8GHz锛夋垨“鐗瑰畾棰戝甫”浠櫒锛堣鐩栫敤鎴锋劅鍏磋叮鐨勭壒瀹氶鐜囷紝濡傜敤浜庡崼鏄熼€氫俊鍜岀數淇″簲鐢ㄧ殑3.7GHz鑷?.2GHz鍜?.9GHz鑷?.4GHz锛夈€傛湰鏂囧皢閲嶇偣璁ㄨ姣旇緝浼犵粺鐨勫甯︽祴璇曚俊鍙锋簮銆傚悗缁枃绔犲皢浠嬬粛鍏跺畠涓€浜涗俊鍙峰彂鐢熷櫒绫诲瀷锛屽寘鎷换鎰忔尝鍙戠敓鍣紙AWG锛夊拰鐭㈤噺淇″彿鍙戠敓鍣紙VSG锛夈€?銆€銆€鍦ㄧ涓€绫诲叿鏈夊璋冭皭鑼冨洿鐨勪俊鍙峰彂鐢熷櫒鍐咃紝Giga-tronics 鍏徃鐨?550B鍨嬩骇鍝侊紙鍥?锛変粎鍑竴鍙颁华鍣ㄥ拰涓€涓紙2.4mm锛夎繛鎺ュ櫒灏辫鐩栦簡2GHz鑷?0GHz鐨勯鐜囪寖鍥达紝骞朵笖閫氳繃涓€涓€夐」杩樺彲浠ユ妸棰戠巼鑼冨洿鎵╁睍鑷?0kHz銆?500B绯诲垪涓繕鏈夊叾瀹冧竴浜涗俊鍙峰彂鐢熷櫒锛屽垎鍒鐩?0kHz鑷?.5GHz銆?GHz鑷?GHz銆?GHz鑷?0GHz銆?GHz鑷?6.5GHz鍜?GHz鑷?0GHz 鐨勯鐜囪寖鍥达紝鎵€鏈夎繖浜涗俊鍙峰彂鐢熷櫒閮藉叿鏈?.001Hz鐨勯鐜囪皟璋愬垎杈ㄧ巼銆傝繖浜涗俊鍙峰彂鐢熷櫒鍙互鎻愪緵璁稿瀵瑰崼鏄熸祴璇曞簲鐢ㄦ潵璇存瀬鏈変环鍊肩殑鐗规€э紝鍖呮嫭澶ц緭鍑哄姛鐜囥€佽緝蹇殑鍒囨崲閫熷害鍜屼綆鐩镐綅鍣０銆傛爣閰嶄笅鐨勮緭鍑哄姛鐜囧湪20GHz浠ヤ笅瓒呰繃+20dBm锛岀ǔ瀹氬埌500MHz浠ヤ笅鐨勬柊棰戠巼鎵€闇€鐨勬椂闂翠笉鍒?50μs锛屽箙搴︾ǔ瀹氭椂闂翠笉鍒?00μs 銆?0GHz杞芥尝锛?kHz鍋忕Щ鏃剁殑鐩镐綅鍣０鏄?102dBc/Hz锛?0GHz杞芥尝锛?0kHz鍋忕Щ鏃剁殑鐩镐綅鍣０鏄?108dBc/Hz锛屽湪50GHz鑼冨洿鍐呰皭娉㈤€氬父灏忎簬-30dBc 锛屾潅鏁ｉ€氬父灏忎簬-50dBc銆?銆€銆€銆€銆€鍥?锛?550B鍨嬩俊鍙峰彂鐢熷櫒鍏锋湁瀹借皟璋愯寖鍥达紝鏍囧噯棰戠巼鑼冨洿鏄?GHz鑷?0GHz锛屽苟鍙墿灞曡嚦10kHz銆?銆€銆€鍦ㄤ簡瑙ｄ簡鏈夊叧棰戣氨绾害鐨勮繖浜涙寚鏍囧悗锛岃繕闇€瑕佹敞鎰忥紝鎬ц兘姘村钩鏄鐜囩殑鍑芥暟锛岀壒鍒槸鍦ㄦ瘮杈冧笉鍚屽埗閫犲晢鐨勪俊鍙峰彂鐢熷櫒鏃躲€備互2550B鍨嬩负渚嬶紝浠?00MHz鐩村埌39.6GHz鑼冨洿鍐呯殑璋愭尝閫氬父鏄?50dBc锛屽湪鏇撮珮鍜屾洿浣庨甯﹁皭娉㈡€ц兘鍒欒緝浣庛€傚悓鏍凤紝鍦ㄧ洿鍒?0.1GHz鐨勯鐜囪寖鍥村唴锛屾潅鏁ｆ€ц兘鍙揪-66dBc锛屽湪10.1GHz鑷?9.6GHz 鑼冨洿鍐呮潅鏁ｆ€ц兘鍙揪-54dBc銆傝繖浜涙€ц兘姘村钩涓嶄粎鏄熀棰戞尟鑽″櫒銆佸熀鍑嗘尟鑽″櫒銆佷骇鐢熶俊鍙峰彂鐢熷櫒寰尝棰戠巼鎵€鐢ㄧ殑棰戠巼鍚堟垚鏂规硶鐨勫嚱鏁帮紝鑰屼笖鏄骇鐢熸渶楂橀甯︽墍鐢ㄧ殑涔樻硶鏂规鐨勫嚱鏁般€?銆€銆€鍏跺畠瀹藉甫鍙板紡淇″彿鍙戠敓鍣ㄥ寘鎷畨鎹蜂鸡绉戞妧鍏徃锛圓gilent Technologies锛夌殑MXG鍜孭SG浠櫒銆丄nritsu鍏徃鐨凪G37000A绯诲垪淇″彿鍙戠敓鍣ㄥ拰缃楀痉涓庢柦鐡﹁尐鍏徃锛圧&S锛夌殑R&S SMF100A寰尝淇″彿鍙戠敓鍣ㄣ€傛墍鏈夎繖浜涗俊鍙峰彂鐢熷櫒閮藉寘鍚揪鍒版绫虫尝棰戠巼鐨勭増鏈紝骞跺叿鏈夊緢濂界殑杈撳嚭鍔熺巼鍜屼紭绉€鐨勯璋辩函搴︺€備緥濡傦紝MXG绯诲垪淇″彿鍙戠敓鍣ㄧ殑棰戠巼鑼冨洿涓?00kHz鑷?0GHz銆?1.8GHz鎴?0GHz锛屽苟涓旈兘鍏锋湁0.01Hz棰戠巼鍒嗚鲸鐜囥€?0GHz浠ヤ笅鐨勬爣鍑嗚緭鍑哄姛鐜囦负+11dBm锛?0GHz鑷?0GHz 鐨勬爣鍑嗚緭鍑哄姛鐜囦负+7dBm锛屽彟鏈夐€夐」鍙皢20GHz浠ヤ笅鐨勮緭鍑哄姛鐜囨彁鍗囪嚦+18dBm锛屽皢20GHz鑷?0GHz鑼冨洿鐨勮緭鍑哄姛鐜囨彁鍗囪嚦+12dBm銆?銆€銆€褰撳伐浣滃湪涓€绯诲垪缂栫▼棰戠巼锛堝垪琛ㄦā寮忥級鏃讹紝浣滀负琛￠噺鍒囨崲鍒扮壒瀹氬垎杈ㄧ巼鍐呯殑鏂伴鐜囨墍闇€鏃堕棿鐨勬寚鏍?mdash;—棰戠巼绋冲畾鏃堕棿鎴栧垏鎹㈤€熷害鍦?ms鎴?ms浠ヤ笅锛堝湪姣旇緝杩欎簺鏁板瓧鏃讹紝璁よ瘑鍒颁笉鍚屽埗閫犲晢鍙兘浣跨敤涓嶅悓鐨勭ǔ瀹氭椂闂村畾涔夊緢閲嶈锛夈€備綔涓轰竴涓彲閫夊姛鑳斤紝鍒囨崲閫熷害鍙互琚姞閫熷埌鍏稿瀷鐨?00μs銆備笌璁稿鍏稿瀷鐨勪俊鍙峰彂鐢熷櫒涓€鏍凤紝鏍囧噯閰嶇疆鏃剁殑杈撳嚭鐢靛钩鍙互闄嶄綆鑷崇害-20dBm锛屽埄鐢ㄩ€夐厤鐨勫唴閮ㄦ杩涜“鍑忓櫒杩樺彲浠ラ檷浣庡埌-90dBm銆傜浉浣嶅櫔澹板吀鍨嬪€兼槸-98dBc/Hz锛?GHz鎴?2GHz杞芥尝锛?0kHz鍋忕Щ锛夈€?0GHz浠ヤ笅鐨勮皭娉㈠吀鍨嬪€间负-60dBc锛?0GHz鑷?0GHz鐨勮皭娉㈠吀鍨嬪€间负-56dBc銆傝€?4GHz浠ヤ笅鐨勬潅鏁ｅ吀鍨嬪€间负-50dBc锛?4GHz鍒?0GHz鏃剁殑鏉傛暎鍏稿瀷鍊兼槸-45dBc銆侻XG淇″彿鍙戠敓鍣ㄦ嫢鏈夊ぇ閲忚皟鍒堕€夐」锛屽寘鎷皟骞咃紙AM锛夈€佽皟棰戯紙FM锛夈€佺浉浣嶈皟鍒跺拰鑴夊啿璋冨埗銆?銆€銆€E8257D鏄畨鎹蜂鸡PSG淇″彿鍙戠敓鍣ㄧ郴鍒椾骇鍝佷腑鐨勪竴绉嶏紝杩欎竴绯诲垪浜у搧鐨勯鐜囪寖鍥磋鐩栦粠250kHz鑷?0GHz銆?1.8GHz銆?0GHz鍜?7GHz锛屽苟涓旀墍鏈変骇鍝佸湪杩炵画娉紙CW锛夊伐浣滄ā寮忎笅鍏锋湁0.001Hz棰戠巼鍒嗚鲸鐜囷紝鍦ㄦ壂鎻忔垨鍒楄〃妯″紡涓嬪叿鏈?.01Hz鍒嗚鲸鐜囥€傛爣鍑嗛鐜囩ǔ瀹氭椂闂村皬浜?ms锛?0GHz浠ヤ笅鐨勪俊鍙疯緭鍑虹數骞宠揪+20dBm銆傚湪鏍囧噯鍨嬪彿浜у搧涓繖浜涜緭鍑哄姛鐜囧彲浠ラ檷浣庤嚦-20dBm锛屽湪甯﹀彲閫夋杩涜“鍑忓櫒鐨勪骇鍝佷腑杈撳嚭鍔熺巼鍙互闄嶄綆鍒?110鎴?135dBm銆傜浉浣嶅櫔澹板吀鍨嬪€间负-107dBc/Hz 锛?0GHz杞芥尝锛?kHz鍋忕Щ锛夛紝鑰?0GHz浠ヤ笅鐨勮皭娉负-55dBc锛?0GHz浠ヤ笅鐨勬潅鏁ｅ吀鍨嬪€间负-58dBc銆?銆€銆€缃楀痉涓庢柦鐡﹁尐鍏徃鐨凴&S SMF100A寰尝淇″彿鍙戠敓鍣ㄥ叿鏈変竴涓潪甯稿鏄撲娇鐢ㄧ殑鍓嶉潰鏉挎樉绀哄睆锛屼笂闈㈡湁鑿滃崟閫夋嫨鍜屾祴璇曠郴缁熻缃紙鍥?锛夈€傛爣鍑嗗瀷鍙蜂骇鍝佺殑棰戠巼鑼冨洿浠?GHz鑷?2GHz锛屽彲浠ラ€氳繃涓€涓€夐」鎵╁睍鑷?00kHz锛岃繕鍙互閫氳繃鍙︿竴涓€夐」鎵╁睍鑷?3.5GHz 銆傞鐜囧垎杈ㄧ巼鏄?.001Hz锛屽吀鍨嬬殑绋冲畾鏃堕棿鏄?ms銆?0GHz浠ヤ笅鐨勮緭鍑哄姛鐜囩害涓?12dBm锛屾爣鍑嗕骇鍝佷腑鍙互闄嶄綆鑷?20dBm锛屽甫鍐呴儴姝ヨ繘琛板噺鍣ㄩ厤浠剁殑浜у搧鍙檷浣庤嚦-130dBm銆?0GHz杞芥尝锛?0kHz鍋忕Щ鏃剁殑鐩镐綅鍣０鍏稿瀷鍊间负-115dBc/Hz锛?0GHz杞芥尝锛?0kHz鍋忕Щ鏃剁殑鍏稿瀷鍊间负-109dBc/Hz。

1981AgilentN5183A M XG MicrowaveAnalog Signal GeneratorData SheetTable of ContentsDefinitions (3)Frequency (4)Amplitude (5)Spectral Purity (8)Analog Modulation (10)Frequency bands (10)Frequency modulation (10)Phase modulation (11)Amplitude modulation (11)Pulse modulation (12)Narrow pulse modulation (13)Internal analog modulation source (14)External modulation inputs (14)Simultaneous modulation (14)General Characteristics (18)Ordering Information (18)Archive (18)Related Literature (18)Application literature (18)Product literature (18)2DefinitionsSpecification (spec):Represents warranted performance of a calibrated instrumentthat has been stored for a minimum of 2 hours within the operating temperature rangeof 0 to 55 °C, unless otherwise stated, and after a 45 minute warm-up period. Thespecifications include measurement uncertainty. Data represented in this documentare specifications unless otherwise noted.Typical (typ):Represents characteristic performance, which 80% of the instrumentsmanufactured will meet. This data is not warranted, does not include measurementuncertainty, and is valid only at room temperature (approximately 25 °C).Nominal (nom): The expected mean or average performance, or an attribute whoseperformance is by design, such as the 50 Ω connector. This data is not warranted andis measured at room temperature (approximately 25 °C).Measured (meas): An attribute measured during the design phase for purposes ofcommunicating expected performance, such as amplitude drift vs. time. This data isnot warranted and is measured at room temperature (approximately 25 °C).Note: All graphs contain measured data from several units at room temperature unlessotherwise noted.3FrequencyRangeOption 520 100 kHz to 20 GHzOption 532 100 kHz to 31.8 GHzOption 540 100 kHz to 40 GHzMinimum frequency 100kHz1Resolution 0.01HzPhase offset Adjustable in nominal 0.01° incrementsFrequency switching speed2, 3Type Standard Option UNZSCPI mode≤ 5 ms≤ 1.15 ms, 750 µs (typ)List/Step sweep mode≤ 5 ms≤ 900 µs, 600 µs (typ)Stability± aging rate± temperature effects± line voltage effectsInternal time base< ±1 ppm/yrreference oscillatoraging rateTemperature effects± 1 ppm (typ) (0 to 55 °C)Line voltage effects± 0.1 ppm (nom)Line voltage range5% to –10% (nom)Reference outputFrequency 10MHzAmplitude ≥ +4 dBm (nom) into 50 Ω loadExternal reference inputFixed Variable (Option 1E R)Input frequency 10 MHz 1 to 50 MHzLock range ± 10 HzAmplitude > –3.5 to 20 dBm (nom)Impedance 50 Ω (nom)Digital sweepOperating modes Step sweep (equally or logarithmically spacedfrequency steps)List sweep (arbitrary list of frequency steps)Can also simultaneously sweep amplitude. Seeamplitude section for more detail.Sweep range Within instrument frequency rangeDwell time 100 μs to 100 sNumber of points 2 to 65535 (step sweep)1 to 1601 (list sweep)Step change Linear or logarithmicTriggering Free run, trigger key, external, timer, bus (GPIB, LAN, USB)Markers In step sweep mode, create up to 20 frequency markersDisplay Z-axis or RF amplitude pulseFunctions M1 to center, M1/M2 to start/stop, marker delta1. Performance below 250 kHz is unspecified, except as indicated.2. Time from receipt of SCPI command or trigger signal to within 0.1 ppm of final frequency or within100 Hz, whichever is greater, and amplitude settled to within 0.2 dB.3. Specification does not apply when switching to or from frequencies < 500 kHz, when ALC level is< –5 dBm for Option 540 or < 0 dBm for Option 520, or when frequency crosses 0.002, 0.02, 0.1, 2.0, 3.2,20.0, 25.6, or 32.0 GHz.45Maximum output power 1 Range Standard 2 Option 1EA 3 Option 520100 to 250 kHz+11+14> 250 kHz to 3.2 GHz +11+15> 3.2 to 20 GHz +11+18Options 532 and 540100 to 250 kHz +11+14250 kHz to 3.2 GHz +7+14> 3.2 to 17 GHz +7+15> 17 to 31.8 GHz +7+13> 31.8 to 40 GHz+7+12Minimum output powerStandard –20 dBm Option 1E1 –90 dBm 4Amplitude1. Quoted specifications between 15 and 35 °C. Maximum output power typically decreases by 0.2 dB/ °C for temperatures outside this range.2. Settable power +2 dB higher than specified.3. Settable power +30 dBm.4. Settable to –130 dBm .Maximum available power Option 520 with Option 1EA (measured)15161718192021222324250200040006000800010000120001400020000Frequency (MHz)A m p l i t u d e (dB m )26271600018000Maximum available power Option 540 with Option 1EA (measured)15161718192021222324250500010000150002000025000300003500040000Frequency (MHz)A m p l i t u d e (dB m )6Resolution 0.01 dB Step attenuator 0 to 115 dB in 5 dB steps(Option 1E1)Amplitude –15 to maximum specified output power with step attenuator hold rangein 0 dB. Can be offset using Option 1E1 mechanical attenuator.Amplitude switching speed 1, 2TypeSCPI mode 2 ms (typ)List/Step sweep mode 2 ms (typ)Absolute level accuracy [dB]3, 4Frequency range –20 to < –10 dBm –10 to +10 dBm> +10 dBm 250 kHz to 2 GHz ±1.4±0.6±0.62 to 20 GHz ±1.3±0.9±0.920 to 40 GHz ±1.3±0.9±1.0Absolute level accuracy with Option 1E1 (dB)4Frequency range –90 to < –75 dBm –75 to < –10 dBm –10 to +10 dBm> +10 dBm 250 kHz to 2 GHz ±1.4±0.7±0.6±0.62 to 20 GHz ±1.6±1.0±0.9±0.920 to 40 GHz ±2.0±1.1±0.9±1.01. Time from receipt of SCPI command or trigger signal to amplitude settled within 0.2 dB.2. Specification does not apply when switching from and to amplitudes where ALC levels are < –5 dBm for Option 540 or < 0 dBm for Option 520.3. Level accuracy applies from –20 dBm to maximum output power between 15 °C and 35 °C.4. For temperatures outside this range, absolute level accuracy degrades by 0.01 dB/degree C forfrequencies ≤ 4.5 GHz and 0.02 dB/degree C for frequencies > 4.5 GHz. For instruments with Type-N connectors (Option 1ED), specifications are degraded typically 0.2 dB above 18 GHz. Specifications do not apply above the maximum specified power.Measured level accuracy Options 520 & 540 at –90 dBm–1–0.8–0.6–0.4–0.200.20.40.60.810500010000150002000025000300003500040000Frequency (MHz)L e v e l a c c u r a c y (d B )Temperature stability0.01 dB/°C (typ) for temperatures < 20 °C or > 30 °C User flatness correctionNumber of points 2 to 1601Number of tables 10000 maximum; dependent on available free memory ininstrumentEntry modes USB/LAN direct power meter control, LAN to GPIB andUSB to GPIB, remote bus and manual USB/GPIB powermeter controlSWR 100 kHz to 20 GHz 1.6:1 (typ)> 20 to 40 GHz 1.8:1 (typ)Leveling modes Internal, external detector, ALC off, searchExternal detector leveling1Range –0.2 mV to –0.5V (nom)Bandwidth 10 kHz (typ)Digital sweep modesOperating modes Step sweep (evenly spaced amplitude steps)List sweep (arbitrary list of amplitude steps)Can also simultaneously sweep frequency. See frequencysection for more detail.Sweep range Within instrument amplitude rangeDwell time 100 μs to 100 sNumber of points 2 to 65535 (step sweep)1 to 1601 (list sweep)Step change LinearTriggering Free run, trigger key, external, timer, bus (GPIB, LAN, USB)1. Not intended for pulsed operation.78Single sideband phase noise (at 20 kHz offset from carrier)Frequency range dBc/Hz dBc/Hz (typ)250 kHz to < 250 MHz –113–116250 to < 375 MHz –125 –128375 to < 750 MHz –119 –122750 MHz to < 1.5 GHz –113 –1161.5 to < 3.0 GHz –107 –1103.0 to < 6.0 GHz –101 –1046.0 to < 12.0 GHz –95 –9812.0 to < 24.0 GHz –89 –9224.0 to 40.0 GHz–83–86Spectral PuritySSB Phase Noise–170–160–150–140–130–120–110–100–90–80–70–60–50–40–30–20–1001010010001000010000010000001E+071E+08L(f) [dBc/Hz] vs. f [Hz]AM noise at 10 GHz–170–160–150–140–130–120–110–100–90–80–70–60–50–40–30–201010010001000010000010000001E+071E+08M(f) (dBc/Hz) vs. f(Hz)Residual FM (CW mode, 0.3 to 3 kHz bandwidth, CITT, RMS)< N*5Hz (typ)Broadband noise CW mode at +10 dBm or maximum specified outputpower, whichever is lower for offsets > 10 MHz0.25 to 10 GHz –145 dBc/Hz (typ)10 to 20 GHz –135 dBc/Hz (typ)20 to 40 GHz –130 dBc/Hz (typ)Harmonics (dBc)1250 kHz to 2 GHz –28 (–30 typ)> 2 to 20 GHz –54 (–60 typ)> 20 to 40 GHz –56 (typ)Non-harmonics (dBc)1, 2250 kHz to 250 MHz –62 (–89 typ)> 250 to 375 MHz –68 (–86 typ)> 375 to 750 MHz –57 (–74 typ)> 750 MHz to 1.5 GHz –54 (–70 typ)> 1.5 to 3.2 GHz –54 (–68 typ)> 3.2 to 6 GHz –47 (–63 typ)> 6 to 12 GHz –41 (–57 typ)> 12 to 24 GHz (–50 typ)> 24 to 40 GHz (–45 typ)Subharmonics (dBc)1250 kHz to 1.5 GHz None> 1.5 GHz to 20 GHz –53> 20 to 40 GHz –501. CW mode at +10 dBm or maximum specified output power, whichever is lower.2. Non-harmonics specifications apply to units with serial numbers ending with 49060000 or greater.For units with lower serial numbers, refer to the archive section at the end of this document.9Analog Modulation Frequency bands1Frequency N100 kHz to < 250 MHz1250 to < 375 MHz0.250375 to < 750 MHz0.500750 to < 1.5 GHz11.5 to < 3.0 GHZ23.0 to < 6.0 GHz46.0 to < 12.0 GHz812.0 to < 24.0 GHz1624.0 to 40 GHz32Frequency modulation(Option UNT)Maximum deviation N x 10 MHz (nom)Resolution 0.1% of deviation or 1 Hz, whichever isgreater (nom)Deviation accuracy< ± 2% + 20 Hz1 kHz rate, deviation is N x 50 kHzModulation frequency response (at 100 kHz deviation)1 dB bandwidth 3 dB bandwidthDC coupled DC to 3 MHz (nom)DC to 7 MHz (nom)AC coupled 5 Hz to 3 MHz (nom) 5 Hz to 7 MHz (nom)Carrier frequency accuracy< ±0.2% of set deviation + (N x 1 Hz)2relative to CW in DCFM < ±0.06% of set deviation + (N x 1 Hz) (typ)3Distortion< 0.4%1 kHz rate, deviation is N x 50 kHzSensitivity when usingexternal input +1V peak for indicated deviation (nom)1. N is a factor used to help define frequency and phase modulation specifications within the document.2. Specification valid for temperature changes of less than ± 5° C since last DCFM calibration.3. Typical performance immediately after a DCFM calibration.10Modulation deviation and frequency response:Max deviation 3 dB bandwidthNominal bandwidth N x 5 radians (nom)DC to 1 MHz (nom)High bandwidth mode N x 0.5 radians (nom)DC to 4 MHz (nom)Resolution0.1% of deviationDeviation accuracy < +0.5% + 0.01 rad (typ)1 kHz rate, normal bandwidth modeDistortion < 0.2% (typ)1 kHz rate, deviation normal bandwidth modeSensitivity when usingexternal input +1V peak for indicated deviation (nom) Amplitude modulation1(Option UNT)ExponentialAM Depth L inear Maximum settable 90% 20 dB Resolution 0.1% of depth (nom) 0.01 dB (nom) Accuracy (1 kHz rate) < ±4% of setting <±(4% of setting+ 1% (typ) + 0.2 dB) (typ)Modulation rate (3 dB bandwidth, 30% depth)DC coupled 0 to 10 kHz (typ)AC coupled 5 Hz to 10 kHz (typ)Distortion (1 kHz rate, 30% depth) < 2.0% (typ)Sensitivity when usingexternal input +1V peak for indicated depth (nom)1. AM is specified at carrier frequencies > 2 MHz, ALC on, and when AM envelope does not exceed maxpower or go below –15 dBm for Option 520 or –20 dBm for Option 540.On/Off ratio > 80 dB (typ)2Rise time < 50 ns (typ)Fall time < 50 ns (typ)Minimum widthALC on ≥ 2 μs (typ)ALC off ≥ 500 ns (typ)Resolution 20 ns (nom)Pulse repetition frequencyALC on DC to 500 kHzALC off DC to 2 MHzLevel accuracy < 1 dB (typ)(relative to CW, ALC on or off)Video feedthrough < 350 mV (typ)Pulse overshoot < 15% (nom)Pulse compression 15 ns (typ)Pulse delayRF delay (video to RF output) 10 ns (nom)Video delay (ext input to video) 30 ns (nom)External inputInput impedance 50 ohm (nom)Level +1 Vpeak = ON (nom)Internal pulse generatorModes Free-run, square, triggered, adjustable doublet,trigger doublet, gated, and external pulse Square wave rate 0.1 Hz to 10 MHz, 0.1 Hz resolution (nom)Pulse period 500 ns to 42 seconds (nom)Pulse width 500 ns to pulse period – 10 ns (nom)Resolution 10 ns (nom)Adjustable trigger delay – pulse period + 10 ns to pulse period to pulsewidth –10 nsSettable delay Free run –3.99 to 3.97 μsTriggered 0 to 40 sResolution 10 ns (nom)(delay, width, period)Pulse doublets1st pulse delay 0 to 42 s – pulse width – 10 ns(relative to sync out)1st pulse width 500 ns to 42 s – delay – 10 ns2nd pulse delay 0 to 42 s – (delay1 + width2) – 10 ns(relative to pulse 1)2nd pulse width 20 ns to 42 s – (delay1 + delay2) – 10 ns1. Pulse specifications apply to frequencies > 500 MHz. Operable down to 10 MHz.2. Applies to power levels > –5 dBm for Option 1E1.Narrow pulse modulation 1(Option UNW) 500 MHz to 3.2 GHz Above 3.2 GHz On/Off ratio> 80 dB (typ) > 80 dB (typ)Rise/Fall times (Tr, Tf) < 10 ns (7 ns) < 10 ns (7 ns)Minimum pulse width Internally leveled ≥ 2 us ≥ 2 us ALC off 2≥ 20 ns≥ 20 ns Repetition frequency Internally leveled 10 Hz to 500 kHz 10 Hz to 500 kHz ALC off 2DC to 5 MHz DC to 10 MHz Level accuracy relative to CW Internally leveled < ±1.0 dB (typ) < ±1.0 dB (typ) ALC off 2±1.0 dB (typ) ±1.0 dB (typ)Width compression< 5 ns (typ) < 10 ns (typ)RF width relative to video out Video feed-through 3 < 300 mV (typ) < 10 mV (typ) Video delay -30 ns (nom) 30 ns (nom) ext input to video RF delay -video to 10 ns (nom)20 ns (nom) RF output Pulse overshoot < 15% (nom) < 15% (nom)Input level +1 Vpeak = RF On +1 Vpeak = RF On Input impedance50 Ω (nom)50 Ω (nom)1. Pulse specifications apply to frequencies > 500 MHz. Operable down to 10 MHz.2. With power search on.3. Applies to power levels < +10 dBm.Td Video delay (variable)Tw Video pulse width (variable)Tp Pulse period (variable)Tm RF delayTrf RF pulse width Tf RF pulse fall time Tr RF pulse rise time Vor Pulse overshoot Vf Video feedthroughInternal analog modulation source(Option UNT)Waveform SineRate range 0.1 Hz to 2 MHz (tunable to 3 MHz) Resolution 0.1 HzFrequency accuracy Same as RF reference source (nom) External modulation inputs(Requires Option UNT)Modulation types FM, AM, phase mod, pulse modInput impedance 50 Ω (nom)Simultaneous modulation1All modulation types (FM, AM, φM and pulse modulation) may be simultaneously enabled except: FM and phase modulation can not be combined; two modulation types can not be simultaneously generated using the same modulation source. For example, AM and FM can run concurrently and will modulate the output RF. This is useful for simulating signal impairments.1. If AM or pulse modulation are on, then phase and FM specifications do not apply.General CharacteristicsRemote programmingInterfaces GPIB IEEE-488.2, 1987 with listen and talkLAN 100BaseT LAN interface, LXI class CcompliantUSB Version 2.0Control languages SCPI Version 1997.0Compatibility languages supporting a subset of common commandsAgilent Technologies 8360 series, E8247C, E8257C, E8257D, E8241A,E8244A, E8251A, E8254A, E4428C, E4438C,E8267C/D, 8662A, 8663A, 83711B, 83712B,83731B, 83732B, 83751B, 83752B, 8340B,8341BPower requirements 100 to 120 VAC, 50 to 60 Hz and 400 Hz220 to 240 VAC, 50 to 60 Hz250 W maximumOperating temperature range 0 to 55 °CStorage temperature range –40 to 70 °COperating and storage altitude 15,000feetEnvironmental stress Samples of this product have been type tested inaccordance with the Agilent Environmental TestManual and verified to be robust against theenvironmental stresses of Storage, Transportationand End-use; those stresses include but are notlimited to temperature, humidity, shock, vibration,altitude and power line conditions. Test Methodsare aligned with IEC 60068-2 and levels aresimilar to MIL-PRF-28800F Class 3.Safety Complies with European Low Voltage Directive73/23/EEC, amended by 93/68/EEC• IEC/EN 61010-1• Canada: CSA C22.2 No. 61010-1• USA: UL 61010-1EMC Complies with European EMC Directive 89/336/EEC, amended by 93/68/EEC• IEC/EN 61326• CISPR Pub 11 Group 1, class A• AS/NZS CISPR 11:2002• IC E S/NMB-001Memory Memory is shared by instrument states, sweep listfiles, and other files. There is 512 MB of flashmemory available in the N5181A MXG. Dependingon how the memory is utilized, a maximum of1000 instrument states can be saved.Security (Option 006) Memory sanitizing, memory sanitizing on poweron, and display blanking.Self test Internal diagnostic routines test most modulesin a preset condition. For each module, if itsnode voltages are within acceptable limits, themodule “passes” the test.Weight ≤ 13.8 kg (30 lb.) net,≤ 28.4 kg (62 lb.) shippingDimensions 103 mm H x 426 mm W x 432 mm L(4.07 in H x 16.8 in W x 17 in L)monthsRecommended calibration cycle 24ISO compliant The Agilent N5181A MXG is manufactured in anISO-9001 registered facility in concurrence withAgilent Technologies’ commitment to quality. Front panel connectors1RF output Output impedance 50 Ω (nom)Option 520 Precision APC-3.5 male, or Type-N withOption 1E DOption 532/540 Precision 2.4 mm male; plus 2.4 – 2.4 mm and2.4 – 2.9 mm female adaptersMaximum reverse power 0.5 W, 0 VdcUSB 2.0 Used with a memory stick for transferringinstrument states, licenses and other files intoor out of the instrument. Also used with U2000series USB average power sensors. For acurrent list of supported memory sticks, visit/find/MXG, click on TechnicalSupport, and refer to FAQs: WaveformDownloadsand Storage.Rear panel connectors1RF output Outputs the RF signal via a precision N type (Option 1EM) female connector.Sweep out Generates output voltage, 0 to +10 V when thesignal generator is sweeping. This output canalso be programmed to indicate when the sourceis settled or output pulse video and is TTL andCMOS compatible in this mode. Outputimpedance < 1 Ω, can drive 2k Ω. Damagelevels are ±15 V.AM External AM input. Nominal input impedance is50 Ω. Damage levels are ±5 V.FM External FM input. Nominal input impedance is50 Ω. Damage levels are ±5 V.Pulse External pulse modulation input. This input isTTL and CMOS compatible. Low logic levels are0 V and high logic levels are +1 V. Nominal inputimpedance is 50 Ω. Input damage levels are≤ –0.3 V and ≥ +5.3 V.1. All connectors are BNC unless otherwise noted.Trigger in This high impedance input accepts TTL andCMOS level signals for triggering point-to-pointin sweep mode. Damage levels are ≤ –0.3 V and≥ +5.3 V.Trigger out Outputs a TTL and CMOS compatible levelsignal for use with sweep mode. The signal ishigh at start of dwell, or when waiting for pointtrigger in manual sweep mode; low when dwellis over or point trigger is received. This outputcan also be programmed to indicate when thesource is settled, pulse synchronization, or pulsevideo. Nominal output impedance is 50 ohms.Input damage levels are ≤ –0.3 V and ≥ +5.3 V. Reference input Accepts a 10 MHz reference signal used tofrequency lock the internal timebase. Option 1ERadds the capability to lock to a frequency from1 MHz to 50 MHz. Nominal input level –3.5 to+20 dBm, impedance 50 Ω.10 MHz out Outputs the 10 MHz reference signal used byinternal time base. Level is nominally +3.9 dBm.Nominal output impedance 50 Ω. Input damagelevel is +16 dBm.USB 2.0 The USB connector provides remote programmingfunctions via SCPI.LAN (100 BaseT) The LAN connector provides the same SCPIremote programming functionality as the GPIBconnector. The LAN connector is also used toaccess the internal web server and FTP server.The LAN supports DHCP, sockets SCPI, VXI-11SCPI, connection monitoring, dynamic host nameservices, TCP keep alive. This interface is LXIclass C compliant.GPIB The GPIB connector provides remoteprogramming functionality via SCPI.ALC input This female BNC connector is used for negativeexternal detector leveling.Input impedance 100 kΩ (nominal)Signal levels –0.2 mV to –0.5 VDamage levels ≤ –12 V and ≥ 1 VZ-axis output This female BNC connector supplies a +5 V(nominal) level during retrace and band switchintervals of a step or list sweep. During step orlist sweep, this connector supplies a –5 V(nominal) level when the RF frequency is at amarker frequency and intensity marker mode ison. The load impedance should be ≥ 5 kΩ.Ordering InformationArchiveRelated Literature N5183A MXG microwave analog signal generatorFrequency520 Frequency range from 100 kHz to 20 GHz532 Frequency range from 100 kHz to 31.8 GHz540 Frequency range from 100 kHz to 40 GHzPerformance enhancementsUNZ Fast frequency switching1E1 Step attenuator1E A HighpowerUNU Pulse modulationUNW Narrow pulse modulationUNT AM, FM, phase modulation006 Instrument security1ER Flexible reference input (1-50 MHz)1EM Move RF output to rear panel1ED Type N RF output connectorAccessories1CM Rackmount kit1CN Front handle kit1CP Rackmount and front handle kit1CR Rack slide kitAXT Transit caseNon-harmonics (dBc)(For serial numbers < 49060000)250 kHz to 250 MHz –54 (–89 typ)> 250 to 375 MHz –61 (–86 typ)> 375 to 750 MHz –55 (–74 typ)> 750 MHz to 1.5 GHz –48 (–70 typ)> 1.5 to 3.2 GHz –47 (–68 typ)> 3.2 to 6 GHz –40 (–63 typ)> 6 to 12 GHz –33 (–57 typ)> 12 to 24 GHz –50 (typ)> 24 to 40 GHz –45 (typ)Application literatureRF Source Basics, a self-paced tutorial (CD-ROM), literature number 5980-2060E Product literatureAgilent MXG Signal Generator, Configuration Guide, literature number 5989-5485EN See the Agilent MXG web page for the latest information. Get the latest news, product and support information, application literature, firmware upgrades and more at /find/MXGRemove all doubtOur repair and calibration services will get your equipment back to you, per-forming like new, when promised. You will get full value out of your Agilent equipment through-out its lifetime. Your equipment will be serviced by Agilent-trained technicians using the latest factory calibration procedures, automated repair diagnostics and genu-ine parts. You will always have the ut-most confidence in your measurements. For information regarding self mainte-nance of this product, please contact your Agilent office.Agilent offers a wide range of addi-tional expert test and measurement services for your equipment, including initial start-up assistance, onsite edu-cation and training, as well as design, system integration, and project man-agement.For more information on repair and calibration services, go to:/find/removealldoubtAgilent Email Updates/find/emailupdates Get the latest information on the products and applications you select.LXI is the LAN-based successor to GPIB, providing faster, more efficient connectivity. Agilent is a founding member of the LXI consortium.Agilent Channel Partnersw w w /find/channelpartners Get the best of both worlds: Agilent’s measurement expertise and product breadth, combined with channel partner convenience.For more information on AgilentTechnologies’ products, applications or services, please contact your local Agilent office. The complete list is available at:/fi nd/contactus Americas Canada(877) 894 4414 Latin America 305 269 7500United States (800) 829 4444Asia Pacifi c Australia 1 800 629 485China800 810 0189Hong Kong 800 938 693India 1 800 112 929Japan 0120 (421) 345Korea 080 769 0800Malaysia 1 800 888 848Singapore 180****8100Taiwan 0800 047 866Thailand1 800 226 008Europe & Middle East Austria 43(0)136****1571Belgium 32 (0) 2 404 93 40 Denmark 45 70 13 15 15Finland 358 (0) 10 855 2100France 0825 010 700**0.125 €/minuteGermany 49 (0) 7031 464 6333 Ireland 1890 924 204Israel 972-3-9288-504/544Italy 39 02 92 60 8484Netherlands 31 (0) 20 547 2111Spain 34 (91) 631 3300Sweden 0200-88 22 55Switzerland 0800 80 53 53United Kingdom 44 (0) 118 9276201Other European Countries: /fi nd/contactusRevised: October 1, 2009Product specifications and descriptions in this document subject to change without notice.© Agilent Technologies, Inc. 2008, 2010Printed in USA, February 23, 20105989-7572EN。

是德科技《信号发生器基础指南》奠定坚实的射频基础—第 1 部分白皮书引言使用可靠的信号源消除测试结果中的不确定性和疑虑更快地进入市场是一场激烈的角逐。

为了赢得胜利，您需要拥有无可置疑的测试结果。

这就是选择合适的仪器至关重要的原因。

您容不得把丝毫的时间浪费在猜测结果上。

本白皮书以信号发生器为主题，分为两部分。

在本文第一部分中，我们将帮助您深入了解信号发生器的基本技术指标，以便您在使用信号发生器时能够做出正确选择。

目录在本白皮书的第 1 部分，主要介绍信号发生器及其基本技术指标，如功率、精度和速度。

我们将在第 2 部分中探讨更高级的功能，如调制、频谱纯度和失真。

第 1 节关键属性了解信号发生器的组成部分以及它相比其他信号源的独特之处。

探索信号发生器的类型和关键技术指标。

第 2 节功率了解平均功率、包络功率和峰值包络功率之间的区别，以及适用于高/低输出功率的测量应用。

第 3 节精度对您的测量结果充满信心。

了解为什么精度很重要，以及需要注意哪种类型的精度。

第 4 节速度对制造业来说，速度就是生命。

更快进入市场，击败竞争对手。

学习如何查看技术指标。

紧跟技术脚步，不要落伍。

第 1 节—关键属性信号发生器种类繁多，它们拥有不同的外形，可以提供不同的功能。

图 1-1. Keysight PXIe 矢量信号发生器和分析仪。

外形：您需要的是台式仪器还是模块化仪器？台式是许多信号发生器的传统外形。

它是我们通常在工作台和机架上看到的典型框式仪器。

这种仪器配备前面板显示器和控件，能让您快速、轻松地设置和调试故障。

台式信号发生器具有全面的功能，覆盖射频到微波以及模拟到矢量的范围。

图 1-2. N5182B MXG X 系列射频矢量信号发生器另一种正在迅速普及的形式是 PXIe。

PXIe 信号发生器的外形紧凑，因此通常用于需要多个通道的应用中。

第三代 PCIe 现在支持最高 24 GB/s 的系统带宽，从而提升了高性能应用（例如采用 FPGA 流处理 streaming 方式将 I/Q 数据传输给基带发生器，或数字预失真应用等）的测试吞吐量。

技术概述X 系列射频信号发生器N5181B/N5171B 模拟信号发生器N5182B/N5172B 矢量信号发生器–频率范围：9 kHz 至 6 GHz–业界领先的性能–先进的实时信号生成–低拥有成本主要技术指标概述MXGEXGCXG频率范围9 kHz 至 6 GHz 9 kHz 至 6 GHz 9 kHz 至 6 GHz 相位噪声（1 GHz ，20 kHz 频偏）–146 dBc/Hz –122 dBc/Hz –119 dBc/Hz 杂散（1 GHz ，非谐波）–96 dBc –72 dBc –72 dBc 输出功率（1 GHz ）+27 dBm +27 dBm +18 dBm ACPR （矢量）W-CDMA 64 DPCH –73 dBc –73 dBc –73 dBc EVM （矢量）802.11ac/LTE 0.4%0.4%0.4%带宽（矢量）160 MHz 160 MHz 120 MHz 任意波形存储器（矢量）1024 MSa512 MSa512 MSa业界领先的性能模拟和矢量 MXG 、EXG 和 CXG 信号发生器支持 9 kHz 至 6 GHz 的频率范围，在五个关键参数上具有极其出色的性能：相位噪声和频谱纯度、带宽、EVM 、ACPR 和输出功率。

先进的实时信号生成通过使用 MXG 或 EXG 和 PathWave 信号生成软件，可根据最新标准执行先进的接收机测试：定义信号参数并将参数传输到仪器，在信号生成过程中进行闭环或交互式控制。

低拥有成本X 系列信号发生器的设计重点考虑的是高可靠性和便捷维护。

自我维护策略便是其中的一个例子：根据我们的部件更换计划可以在两小时内完成现场维修。

/find/X-Series_SG生成真正性能您需要采取多种途径来了解器件的特性，这正是 Keysight X 系列信号发生器的设计理念。

它们可以生成您需要的信号 — 从简单信号到复杂信号，从纯净信号到有损信号，以便对您的设计进行极限甚至超出极限的测试。

是德科技MXG X 系列信号发生器N5183B 微波模拟9 kHz 至 13、20、31.8 或 40 GHz技术资料定义技术指标(spec):技术指标是指已校准的仪器能够保证的参数性能，除非另有说明，仪器已在0 至55 °C 的工作温度范围内放置了至少2 小时，又经过45 分钟预热。

技术指标包括测量的不确定度。

对于本文中的数据，如无另行说明均为技术指标。

典型值(typ):典型值是指不在产品保证范围之内的其它产品性能信息。

在室温 (约25 °C) 条件下，约80% 的仪表在95% 的置信度下，其性能会超过技术指标值，典型值不包括测量不确定度。

标称值(nom) 或测量值(meas):标称值 (nom) 或测量值 (meas) 表示为了和采样或平均性能进行比较, 在设计阶段所测得的性能特征, 例如 50 Ω连接器或幅度漂移随时间的变化。

该数据没有保证, 并在室温(约25 °C) 条件下测得。

频率技术指标1. 从接收到SCPI 命令或触发信号至最终频率在0.1 ppm 或100 Hz 以内, 时间取两者中较大值。

2. 因出口管制, 在最终频率的0.05% 之内, 连续波切换速度是190 us (测量值)。

3. 因出口管制, 在最终频率的0.05% 以内, 连续波切换速度大于400 us (标称值)(频率低于20 GHz) 或大于600 us (标称值)(高于20 GHz)。

4. 技术指标仅在状态寄存器更新关闭时适用。

输入频率, 标配10 MHz输入频率, 选件1ER 1 至50 MHz (0.1 Hz 的倍数)锁定范围±1 ppm (标称值)幅度 5 dBm ±2 dB (标称值) 2阻抗50 Ω (标称值)波形正弦波或方波扫描模式(频率和幅度)工作模式步进扫描(相同间隔或对数间隔频率步进)列表扫描(频率步进和幅度步进的任意列表)使用N5172B 同时扫描波形; 如欲了解详情, 参见“基带发生器”章节扫描范围在仪器的频率范围内驻留时间100 μs 100s点数2 至65535 (步进扫描) 1 至3201 (列表扫描)步进变化线性或对数触发自由运行、触发键、外部、计时器、总线(GPIB、LAN、USB)1. 老化率由设计决定, 并与OCXO 有直接关系。

矢量信号发生器技术参数
矢量信号发生器是一种用于生成复杂信号的电子设备，可用于测试和
验证无线电频率、调制和编解码器等相关设备。

其技术参数如下：
1. 频率范围：矢量信号发生器的频率范围通常为几千赫兹到数千兆赫
兹之间，具体的频率范围取决于设备的型号和技术水平。

2. 调制类型：矢量信号发生器通常支持各种调制类型，如调幅、调频、调相、多路复用等。

其中，调制深度和带宽也是设备主要考虑的参数。

3. 功率范围：矢量信号发生器的输出功率通常为几微瓦至数瓦之间，
具体的功率范围也取决于设备的型号和技术水平。

4. 输出阻抗：输出阻抗是矢量信号发生器输出信号的电学特性，通常
为50欧姆以适配测试设备。

5. 附加功能：矢量信号发生器还可以配备多种附加功能，如多通道输出、任意波形发生、频谱分析等。

上述技术参数直接影响了矢量信号发生器在无线电测试应用中的使用
效果。

不同的测试需求需要选择不同的技术参数的设备，以达到最佳
的测试效果。

同时，矢量信号发生器的技术水平和工艺也对设备的性能产生重要影响。

随着科技水平的不断提升，矢量信号发生器的性能也会不断提升，为无线电测试应用提供更精确和准确的测试手段。

矢量信号发生器的技术指标矢量信号发生器是一种用于产生特定类型的信号的电子设备。

这种设备通常用于测试、校准和调试其他电子设备，以确保它们的性能符合规格。

在本文中，我们将介绍矢量信号发生器的各种技术指标，包括频率范围、调制方式、输出功率等。

频率范围频率范围通常是矢量信号发生器的一个关键技术指标。

它表示设备可以生成的信号频率的范围。

这个范围通常会在设备的规格中列出，例如从几千兆赫兹到几十吉赫兹。

一般来说，频率范围越宽，设备能够产生的信号类型就越多。

调制方式矢量信号发生器支持的调制方式也是其中一个重要的技术指标。

这个指标描述了设备可以使用的调制类型，例如振幅、相位、频率、脉冲、调频等等。

这些不同的调制方式可以使设备用于不同种类的测试和应用场景。

输出功率输出功率是矢量信号发生器的另一个关键技术指标。

它表示设备可以在其输出端口提供的信号功率水平。

这个指标通常是以分贝为单位显示，例如从-120分贝到+10分贝。

输出功率越高，设备就可以提供高强度的信号。

在测试高灵敏度的接收器时，低功率输出通常更合适。

调制带宽调制带宽是指信号发生器支持的最大调制频率。

它通常是一个在设备规格中列出的数字，表示设备可以支持的最高调制速率。

这个指标对于高速通讯系统的测试和校准非常重要。

相位噪声相位噪声是指相邻频率上频率差为1赫兹的单频调制信号的相位差的随机偏差。

它是矢量信号发生器的另一个关键技术指标，表示设备输出信号的稳定性。

相位噪声通常以日志单位分贝为单位显示，例如从-100分贝/赫兹到-150分贝/赫兹。

相位噪声越低，设备输出的信号就越稳定。

其他指标除了上述示例指标之外，矢量信号发生器还有许多其他的技术指标。

例如，输出信号的谐波失真程度、标称电阻、输入/输出阻抗、信号标准（如Wi-Fi、LTE等）等等。

这些指标通常会因设备不同而有所不同，因此在购买前需要进行仔细比较。

结论矢量信号发生器是一种非常重要的测试和校准设备，用于测试和校准各种类型的通信和无线电设备。

DefinitionsSpecification (spec):Specifications represent warranted performance of a calibrated instrument that has been stored for a minimum of 2 hours within the operating temperature range of 0 to 55 °C, unless otherwise stated, and after a 45 minute warm-up period. The specifications include measurement uncertainty. Data represented in this document are specifications unless otherwise noted.Typical (typ):Typical (typ) describes additional product performance information. It is performance beyond specifications that 80 percent of the units exhibit with a95 percent confidence level at room temperature (approximately 25 °C). Typical performance does not include measurement uncertainty.Nominal (nom) or measured (meas):Nominal (nom) or measured (meas) describes a performance attribute that is by design or measured during the design phase for the purpose of communicating sampled, mean or average performance, such as the 50 ohm connector or amplitude drift vs. time. This data is not warranted and is measured at room temperature (approximately 25 °C).Frequency Specifications2. For export control purposes CW switching speed to within 0.05% of final frequency is 190 us (meas).3. For export control purposes CW switching speed to within 0.05% of final frequency is > 400 us (nom) below 20 GHz and > 600 us (nom) above 20 GHz.4. Specifications apply when status register updates are off.2. After one year of operation, aging rate drops to < ± 3 x 10^-8 per year or ± 30 ppb/year.3. Inputs between +3 dBm to +20 dBm are allowed.Amplitude Specifications1. Quoted specifications between 15 and 35 °C. Maximum output power typically decreases by 0.05 dB/°C for temperatures outside thisrange.level accuracy degrades by 0.01 dB/degree C for frequencies ≤ 4.5 GHz and 0.02 dB/degree C for frequencies > 4.5 GHz.2. For instruments with Type-N connectors (Option 1ED), specifications are degraded typically 0.2 dB above 18 GHz.2. Time from receipt of SCPI command or trigger signal to amplitude settled within 0.2 dB. Specification does not apply when switching to or from frequencies < 5MHz, or when ALC level is < 0 dBm, or when frequency crosses 0.002, 0.02, 0.1, 2.0, 3.2, 5.0, 6.4, 8, 10, 12.8, 16, 20, 25.6, or 32 GHz.3. When ALC is off and power search mode is disabled amplitude switching is < 250 us (meas).Spectral Purity Specifications2. Specifications apply from +15 to +35 °C and are nominal for harmonics beyond specified frequency range.3. Or maximum specified output power, whichever is lower.Option 520 harmonics at +10 dBm (measured)Frequency (MHz)–30–40–50–60–70–80–905000100001500020000250002n d h a r m o n i c (d B c )Option 540 harmonics at +10 dBm (measured)Frequency (MHz)–30–40–50–60–70–80–905000100001500020000250002n d h a r m o n i c (d B c )Option 540 harmonics at +20 dBm (measured)Frequency (MHz)–30–40–50–60–70–80–9005000100001500020000250002n d h a r m o n i c (d B c )2n d h a r m o n i c (d B c )Option 520 harmonics at +20 dBm (measured)Frequency (MHz)–30–40–50 –60–70–80–905000100001500020000250002. Power line related non-harmonics : 60 Hz to 300 Hz: < –50 dBc. Measured from 1 MHz to 40 GHz.Analog Modulation Specifications2. Specification applies from 15 to 35 °C.3. Specification valid for temperature changes of less than ± 5 °C since last DC calibration.4. Typical performance immediately after a DC calibration.2. ALC off is used for narrow pulse modulation and/or high AM depths with envelope peaks below ALC operating range. Carrier power level will be accurate after apower search is executed.3. Deep AM with ALC on provides increased AM depths and improved distortion, together with closed-loop internal leveling. This mode requires a repetitive AMwaveform (frequency > 10 Hz) with peaks > –5 dBm (nom), excluding step-attenuator setting).4. ± 2 dB @ 40 dB, and 50 dB < 31.8 GHz, and ± 4 dB @ 50 dB > 31.8 GHz (meas).5. From 5 MHz to 50 MHz carrier roll off is < 5 dB at 50 kHz rate. From 50 MHz to 3.2 GHz rate is useable up to 100 kHz. Above 3.2 GHz rate is useable to 1 MHz.2. Above 35 GHz vernier > 0 dBm.3. For export control purposes, Option UW2 limits minimum pulse width above 31.8 GHz to ≥ 500 ns.4. With power search on.1. Video feed through applies to power levels < +10 dBm.2. For export control purposes, Option UW2 limits minimum pulse width above 31.8 GHz to ≥ 500 ns.General Characteristics220 or 240 VAC, 50 or 60 Hz– I EC/EN 61326– C ISPR Pub 11 Group 1, class A– A S/NZS CISPR 11– I CES/NMB-001up to 8 GB. Depending on how the memory is utilized, a maximum of 1000 instrument states can be saved.Security (Option 006)Option 006 “Removable memory card & Instrument security” allows the following:– R emovable 8 GB solid state memory (SD card) from rear pane.– U ser can force all files to be stored only on external memory card including instrument states, user data files, sweep list files, and other files– M emory sanitizing, memory sanitizing on power on, and display blanking– D isable USB portsSelf-testInternal diagnostic routines test most modules in a preset condition. For each module, if its node voltages are within acceptable limits, the module “passes” the test.WeightN5183B-513/520: ≤ 14.5 kg (32 lb.) net, ≤ 29.5 kg (65 lb.) shippingN5183B-532/540: ≤ 15.0 kg (33 lb.) net, ≤ 29.9 kg (66 lb.) shippingDimensions88 mm H x 426 mm W x 489 mm L (length includes rear panel feet)(3.5 in H x 16.8 in W x 19.2 in L)Max length (L) including RF connector tip to end of rear panel feet is 508 mm (20 in)Recommended calibration cycle36 monthsISO compliantThis instrument is manufactured in an ISO-9001 registered facility in concurrence with Keysight Technologies’ commitment to quality.Inputs and OutputsRelated LiteratureKeysight X-Series Signal GeneratorsEXG Microwave Signal Generator Data Sheet 5991-3132EN Microwave Signal Generator Flyer 5991-3594ENX-Series Signal Generator Brochure 5990-9957EN/find/N5183B21 | Keysight | MXG X-Series Signal Generator N5183B Microwave Analog - Data SheetThis information is subject to change without notice.© Keysight Technologies, 2017Published in USA, December 2, 20175991-3131ENFor more information on KeysightTechnologies’ products, applications or services, please contact your local Keysight office. The complete list is available at:/find/contactus Americas Canada (877) 894 4414Brazil 55 11 3351 7010Mexico001 800 254 2440United States (800) 829 4444Asia Pacific Australia 1 800 629 485China800 810 0189Hong Kong 800 938 693India 1 800 11 2626Japan 0120 (421) 345Korea 080 769 0800Malaysia 1 800 888 848Singapore 180****8100Taiwan0800 047 866Other AP Countries (65) 6375 8100Europe & Middle East Austria 0800 001122Belgium 0800 58580Finland 0800 523252France 0805 980333Germany ***********Ireland 1800 832700Israel 1 809 343051Italy800 599100Luxembourg +32 800 58580Netherlands 0800 0233200Russia 8800 5009286Spain 800 000154Sweden 0200 882255Switzerland0800 805353Opt. 1 (DE)Opt. 2 (FR)Opt. 3 (IT)United Kingdom0800 0260637For other unlisted countries:/find/contactus (BP-9-7-17)/go/quality Keysight Technologies, Inc.DEKRA Certified ISO 9001:2015Quality Management SystemEvolving Since 1939Our unique combination of hardware, software, services, and people can help you reach your next breakthrough. We are unlocking the future of technology. From Hewlett-Packard to Agilent to Keysight.myKeysight/find/mykeysightA personalized view into the information most relevant to you. /find/emt_product_registrationRegister your products to get up-to-date product information and find warranty information.Keysight Services/find/serviceKeysight Services can help from acquisition to renewal across your instrument’s lifecycle. Our comprehensive service offerings—one-stop calibration, repair, asset management, technology refresh, consulting, training and more—helps you improve product quality and lower costs.Keysight Assurance Plans/find/AssurancePlansUp to ten years of protection and no budgetary surprises to ensure your instruments are operating to specification, so you can rely on accurate measurements.Keysight Channel Partners/find/channelpartnersGet the best of both worlds: Keysight’s measurement expertise and product breadth, combined with channel partner convenience.。

信号的技术参数信号是指一种能够传达信息的电子、电磁或其他形式的波动。

在通信、电子设备和各种系统中，信号的技术参数对于系统的性能和稳定性是非常重要的。

接下来我们将对信号的技术参数进行详细介绍，希望对你有所帮助。

一、信号的类型信号根据传输介质可以分为模拟信号和数字信号两种类型。

模拟信号是连续变化的信号，而数字信号则是离散的信号。

在通信和电子设备中，常常需要将模拟信号转换成数字信号，或者将数字信号转换成模拟信号来实现信息的传输和处理。

二、信号的频率频率是信号的重要技术参数，表示信号每秒内变化的次数，单位为赫兹（Hz）。

在通信系统中，频率的选择会影响到信号的传输距离、抗干扰能力以及系统的带宽需求等。

在移动通信系统中，不同频段的信号传输特性和覆盖范围都有所不同。

三、信号的幅度幅度是信号的另一个重要技术参数，代表信号的大小或强度。

在通信系统中，信号的幅度决定了信号的传输距离和传输质量。

信号的幅度可以通过增益和衰减来调节，以满足系统的需要。

四、信噪比信噪比是指在信号中有用信号功率与噪声功率之比，通常以分贝（dB）为单位表示。

信噪比是衡量信号质量的重要参数，在通信系统中，信噪比越高，表示信号中有用信息的比重越大，传输质量越好。

五、带宽带宽是信号频率范围的宽度，通常以赫兹为单位。

带宽是决定信号传输速率和信息容量的重要参数，不同类型的信号需要的带宽也会有所不同。

在数字通信系统中，带宽的分配和管理对于系统的性能和效率至关重要。

六、谐波失真当信号被非线性系统传输时，会产生谐波失真。

这会导致信号的频率成分发生畸变，影响信号的质量和准确性。

在设计和使用信号传输系统时，需要特别关注谐波失真的控制和补偿。

七、时延时延是信号传输过程中的延迟时间，也是信号的重要技术参数之一。

在通信系统中，时延会对数据传输和实时性产生影响。

准确控制和管理时延，对于提高系统的效率和性能至关重要。

总结信号的技术参数是通信、电子设备和系统设计中的关键因素，了解和掌握这些技术参数对于优化系统性能和功能是非常重要的。