產品型號:VK1621B 產品品牌:VINTEK/元泰 封裝形式:LQFP48 LQFP44 SSOP48 DIP28 DICE/裸片 COB邦定片 定制COG 產品年份:新年份 聯 系 人:許先生 聯系手機:18898582398 工程服務,技術支持,價格具有優勢! VK1621B 是128模式(32x4),內存映射和多功能液晶驅動程序。S / W的VK1621配置特性使得它適合于多種LCD應用包括液晶顯示模塊和顯示子系統。只用三或四線的主機控制器連接VK1621之間的接口要求。VK1621包含一個電源關閉命令來降低功耗。 VK1621產品特征: ★ 工作電壓:2.4V ~ 5.2V ★ 內置RC振蕩器 ★ 外部的32.768kHz晶體或喚頻率源的輸入 ★ 1 / 2或1 / 3 偏壓選擇,和1 / 2或1 / 3或1 / 4液晶顯示應用程序的選擇 ★內部時間基準頻率源 ★兩個可選蜂鳴器的頻率(2/3) ★關機命令降低功耗 ★內置的時基發生器和看門狗 ★ 時基或WDT溢出輸出 ★ 8種時基/定時器的時鐘源 ★ 32x4 LCD驅動器 ★內置32x4位顯示RAM ★ 三線串行接口 ★ 內部LCD驅動頻率源 ★軟件配置特征 ★ 數據模式和命令模式指令的R / W地址自動遞增 ★三種數據訪問模式 ★提供 VLCD引腳來調整 LCD 工作電壓 ★ 此篇產品敘述為功能簡介,如需要完整產品PDF資料可以聯系許先生索取聯系電話:18898582398 LCD/LED液晶控制器及驅動器系列 芯片簡介如下: RAM映射LCD控制器和驅動器系列 VK1024B 2.4V~5.2V 6seg*4com 6*3 6*2 偏置電壓1/2 1/3 S0P-16 VK1056B 2.4V~5.2V 14seg*4com 14*3 14*2 偏置電壓1/2 1/3 SOP-24/SSOP-24 VK1072B 2.4V~5.2V 18seg*4com 18*3 18*2 偏置電壓1/2 1/3 SOP-28 VK1072C 2.4V~5.2V 18seg*4com 18*3 18*2 偏置電壓1/2 1/3 SOP-28 VK1088B 2.4V~5.2V 22seg*4com 22*3 偏置電壓1/2 1/3 QFN-32L(4MM*4MM) VK0192 2.4V~5.2V 24seg*8com 偏置電壓1/4 LQFP-44 VK0256 2.4V~5.2V 32seg*8com 偏置電壓1/4 QFP-64 VK0256B 2.4V~5.2V 32seg*8com 偏置電壓1/4 LQFP-64 VK0256C 2.4V~5.2V 32seg*8com 偏置電壓1/4 LQFP-52 VK1621S-1 2.4V~5.2V 32*4 32*3 32*2 偏置電壓1/2 1/3 LQFP44/48/SSOP48/SKY28/DICE裸片 VK1622B 2.7V~5.5V 32seg*8com 偏置電壓1/4 LQFP-48 VK1622S 2.7V~5.5V 32seg*8com 偏置電壓1/4 LQFP44/48/52/64/QFP64/DICE裸片 VK1623S 2.4V~5.2V 48seg*8com 偏置電壓1/4 LQFP-100/QFP-100/DICE裸片 VK1625 2.4V~5.2V 64seg*8com 偏置電壓1/4 LQFP-100/QFP-100/DICE VK1626 2.4V~5.2V 48seg*16com 偏置電壓1/5 LQFP-100/QFP-100/DICE (高品質 高性價比:液晶顯示驅動IC 原廠直銷 工程技術支持!) (所有型號全部封裝均有現貨,歡迎加Q查詢 191 888 5898 許生) 高抗干擾LCD液晶控制器及驅動系列 VK2C21A 2.4~5.5V 20seg*4com 16*8 偏置電壓1/3 1/4 I2C通訊接口 SOP-28 VK2C21B 2.4~5.5V 16seg*4com 12*8 偏置電壓1/3 1/4 I2C通訊接口 SOP-24 VK2C21C 2.4~5.5V 12seg*4com 8*8 偏置電壓1/3 1/4 I2C通訊接口 SOP-20 VK2C21D 2.4~5.5V 8seg*4com 4*8 偏置電壓1/3 1/4 I2C通訊接口 NSOP-16 VK2C22A 2.4~5.5V 44seg*4com 偏置電壓1/2 1/3 I2C通訊接口 LQFP-52 VK2C22B 2.4~5.5V 40seg*4com 偏置電壓1/2 1/3 I2C通訊接口 LQFP-48 VK2C23A 2.4~5.5V 56seg*4com 52*8 偏置電壓1/3 1/4 I2C通訊接口 LQFP-64 VK2C23B 2.4~5.5V 36seg*8com 偏置電壓1/3 1/4 I2C通訊接口 LQFP-48 VK2C24 2.4~5.5V 72seg*4com 68*8 60*16 偏置電壓1/3 1/4 1/5 I2C通訊接口 LQFP-80 超低功耗LCD液晶控制器及驅動系列 VKL060 2.5~5.5V 15seg*4com 偏置電壓1/2 1/3 I2C通訊接口 SSOP-24 VKL128 2.5~5.5V 32seg*4com 偏置電壓1/2 1/3 I2C通訊接口 LQFP-44 VKL144A 2.5~5.5V 36seg*4com 偏置電壓1/2 1/3 I2C通訊接口 TSSOP-48 VKL144B 2.5~5.5V 36seg*4com 偏置電壓1/2 1/3 I2C通訊接口 QFN48L (6MM*6MM) 靜態顯示LCD液晶控制器及驅動系列 VKS118 2.4~5.2V 118seg*2com 偏置電壓 -- 4線通訊接口 LQFP-128 VKS232 2.4~5.2V 116seg*2com 偏置電壓1/1 1/2 4線通訊接口 LQFP-128 內存映射的LED控制器及驅動器 VK1628 --- 通訊接口:STB/CLK/DIO 電源電壓:5V(4.5~5.5V) 驅動點陣:70/52 共陰驅動:10段7位/13段4位 共陽驅動:7段10位 按鍵:10x2 封裝SOP28 VK1629 --- 通訊接口:STB/CLK/DIN/DOUT 電源電壓:5V(4.5~5.5V) 驅動點陣:128 共陰驅動:16段8位 共陽驅動:8段16位 按鍵:8x4 封裝QFP44 VK1629A --- 通訊接口:STB/CLK/DIO 電源電壓:5V(4.5~5.5V) 驅動點陣:128 共陰驅動:16段8位 共陽驅動:8段16位 按鍵:--- 封裝SOP32 VK1629B --- 通訊接口:STB/CLK/DIO 電源電壓:5V(4.5~5.5V) 驅動點陣:112 共陰驅動:14段8位 共陽驅動:8段14位 按鍵:8x2 封裝SOP32 VK1629C --- 通訊接口:STB/CLK/DIO 電源電壓:5V(4.5~5.5V) 驅動點陣:120 共陰驅動:15段8位 共陽驅動:8段15位 按鍵:8x1 封裝SOP32 VK1629D --- 通訊接口:STB/CLK/DIO 電源電壓:5V(4.5~5.5V) 驅動點陣:96 共陰驅動:12段8位 共陽驅動:8段12位 按鍵:8x4 封裝SOP32 VK1640 --- 通訊接口: CLK/DIN 電源電壓:5V(4.5~5.5V) 驅動點陣:128 共陰驅動:8段16位 共陽驅動:16段8位 按鍵:--- 封裝SOP28 VK1650 --- 通訊接口: SCL/SDA 電源電壓:5V(3.0~5.5V) 驅動點陣:8x16 共陰驅動:8段4位 共陽驅動:4段8位 按鍵:7x4 封裝SOP16/DIP16 VK1668 ---通訊接口:STB/CLK/DIO 電源電壓:5V(4.5~5.5V) 驅動點陣:70/52 共陰驅動:10段7位/13段4位 共陽驅動:7段10位 按鍵:10x2 封裝SOP24 VK6932 --- 通訊接口:STB/CLK/DIN 電源電壓:5V(4.5~5.5V) 驅動點陣:128 共陰驅動:8段16位17.5/140mA 共陽驅動:16段8位 按鍵:--- 封裝SOP32 VK16K33 --- 通訊接口:SCL/SDA 電源電壓:5V(4.5V~5.5V) 驅動點陣:128/96/64 共陰驅動:16段8位/12段8位/8段8位 共陽驅動:8段16位/8段12位/8段8位 按鍵:13x3 10x3 8x3 封裝SOP20/SOP24/SOP28 (所有型號全部封裝均有現貨,歡迎加Q查詢 191 888 5898 許生) 以上介紹內容為IC參數簡介,難免有錯漏,且相關IC型號眾多,未能一一收錄。歡迎聯系索取完整資料及樣品! 請加許先生 QQ:191 888 5898聯系!謝謝 生意無論大小,做人首重誠信!本公司全體員工將既往開來,再接再厲。爭取為各位帶來更專業的技術支持,更優質的銷售服務,更高性價比的好產品.竭誠希望能與各位客戶朋友深入溝通,攜手共進,共同成長,合作共贏!謝謝。
上傳時間: 2020-05-25
上傳用戶:2937735731
This book gives a comprehensive overview of the technologies for the advances of mobile radio access networks. The topics covered include linear transmitters, superconducting filters and cryogenic radio frequency (RF) front head, radio over fiber, software radio base stations, mobile terminal positioning, high speed downlink packet access (HSDPA), multiple antenna systems such as smart antennas and multiple input and multiple output (MIMO) systems, orthogonal frequency division multiplexing (OFDM) systems, IP-based radio access networks (RAN), autonomic networks, and ubiquitous networks.
標簽: Advances Networks Access Mobile Radio in
上傳時間: 2020-05-26
上傳用戶:shancjb
Emerging technologies such as WiFi and WiMAX are profoundly changing the landscape of wireless broadband. As we evolve into future generation wireless networks, a primary challenge is the support of high data rate, integrated multi- media type traffic over a unified platform. Due to its inherent advantages in high-speed communication, orthogonal frequency division multiplexing (OFDM) has become the modem of choice for a number of high profile wireless systems (e.g., DVB-T, WiFi, WiMAX, Ultra-wideband).
標簽: Broadband Wireless Networks
上傳時間: 2020-05-26
上傳用戶:shancjb
The design and manufacturing of wireless radio frequency (RF) transceivers has developed rapidly in recent ten yeas due to rapid development of RF integrated circuits and the evolution of high-speed digital signal processors (DSP). Such high speed signal processors, in conjunction with the development of high resolution analog to digital converters and digital to analog converters, has made it possible for RF designers to digitize higher intermediate frequencies, thus reducing the RF section and enhancing the overall performance of the RF section.
標簽: Transceivers Wireless Digital
上傳時間: 2020-05-27
上傳用戶:shancjb
Wireless Fidelity (Wi-Fi) networks have become mainstream over the last few years. What started out as cable replacement for static desktops in indoor networks has been extended to fully mobile broadband applications involving moving vehicles, high-speed trains, and even airplanes.
標簽: Technologies Emerging Wireless Theory LANs in
上傳時間: 2020-05-27
上傳用戶:shancjb
With the rapid growth in the number of wireless applications, services and devices, using a single wireless technology such as a second generation (2G) and third gener- ation (3G) wireless system would not be efficient to deliver high speed data rate and quality-of-service (QoS) support to mobile users in a seamless way. The next genera- tion wireless systems (also sometimes referred to as Fourth generation (4G) systems) are being devised with the vision of heterogeneity in which a mobile user/device will be able to connect to multiple wireless networks (e.g., WLAN, cellular, WMAN) simultaneously.
標簽: Heterogeneous Wireless Networks Access
上傳時間: 2020-05-27
上傳用戶:shancjb
The first Third Generation Partnership Project (3GPP) Wideband Code Division Multiple Access (WCDMA) networks were launched during 2002. By the end of 2005 there were 100 open WCDMA networks and a total of over 150 operators having frequency licenses for WCDMA operation. Currently, the WCDMA networks are deployedinUniversalMobileTelecommunicationsSystem(UMTS)bandaround2GHz in Europe and Asia including Japan and Korea. WCDMA in America is deployed in the existing 850 and 1900 spectrum allocations while the new 3G band at 1700/2100 is expected to be available in the near future. 3GPP has defined the WCDMA operation also for several additional bands, which are expected to be taken into use during the coming years.
標簽: HSDPAHSUPA Access Speed Radio UMTS High for
上傳時間: 2020-05-27
上傳用戶:shancjb
IPC BatchTool 使用方法指引
上傳時間: 2020-05-28
上傳用戶:libiao820514
With the rapid growth of the wireless mobile applications, wireless voice has begun to challenge wireline voice, whereas the desire to access e-mail, surf the Web or download music (e.g., MP3) wirelessly is increasing for wireless data. While second generation (2G) cellular wireless systems, such as cdmaOne1, GSM2 and TDMA3, introduced digital technology to wireless cellular systems to deal with the increasing demand for wireless applications, there is still the need for more spectrally efficient technologies for two reasons. First, wireless voice capacity is expected to continue to grow. Second, the introduction of high-speed wireless data will require more bandwidth.
標簽: Wireless Systems Mobile Beyond and 3G
上傳時間: 2020-05-30
上傳用戶:shancjb
Emerging technologies such as WiFi and WiMAX are profoundly changing the landscape of wireless broadband. As we evolve into future generation wireless networks, a primary challenge is the support of high data rate, integrated multi- media type traffic over a unified platform. Due to its inherent advantages in high-speed communication, orthogonal frequency division multiplexing (OFDM) has become the modem of choice for a number of high profile wireless systems (e.g., DVB-T, WiFi, WiMAX, Ultra-wideband).
標簽: OFDM-Based Broadband Networks Wireless
上傳時間: 2020-05-31
上傳用戶:shancjb
