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特性
- Four differential transmitters (Tx)
- Four differential receivers (Rx)
- Two differential observation receivers (ORx)
- Tunable range: 600 MHz to 6000 MHz
- Single-band and multiband (N x 2T2R/4T4R) capability
- Four individual band profiles within tunable range (band profiles define bandwidth and aggregate sampling rate of a channel)
- ADRV9044BBPZ-WB supports DPD for 400 MHz iBW/OBW
- Simplifying system thermal solution
- Power consumption-optimized DFE engines
- 125°C maximum junction temperature for intermittent operation, 110°C for continuous (operating lifetime impact at >110°C can be offset by operation at <110°C based on acceleration factors)
- Fully integrated DFE (DPD, CDUC, CDDC, and CFR) engine that reduces FPGAs resources and halves SERDES lane rate
- DPD adaptation engine for power amplifier linearization
- CDUC/CDDC—maximum eight component carriers (CCs) per each transmitter/receiver channel
- Multistage CFR engine
- Supports DTx (micro sleep) power saving mode in downlink
- Supports JESD204B and JESD204C digital interface
- Multichip phase synchronization for all local oscillator (LO) and baseband clocks
- Dual fully integrated fractional-N RF synthesizers
- Fully integrated clock synthesizer
The ADRV9044 is a highly integrated, system on chip (SoC) RF agile transceiver with integrated digital front end (DFE). The SoC contains four transmitters, two observation receivers to monitor transmitter channels, four receivers, integrated LO and clock synthesizers, and digital signal processing functions. The SoC meets the high radio performance and low power consumption demanded by cellular infrastructure applications including small cell base-station radios, macro 3G/4G/5G systems, and massive MIMO base stations.
The receiver and transmitter signal paths use a zero-IF (ZIF) architecture that provides wide bandwidth with dynamic range suitable for contiguous and non-contiguous multi-carrier base-station applications. The ZIF architecture has the benefits of low power plus RF frequency and bandwidth agility. The lack of aliases and out-of-band images eliminate anti-aliasing and image filters. This reduces both system size and cost, also making band independent solutions possible.
The device also includes two wide-bandwidth observation path receiver subsystems to monitor transmitter outputs. This SoC subsystem includes automatic and manual attenuation control, DC offset correction, quadrature error correction (QEC), and digital filtering. GPIOs that provide an array of digital control options are also integrated.
Multi-band capability is enabled by additional LO dividers and wideband operation. This allows two individuals band profiles within the tunable range, so maximizing use case flexibility.
The SoC has fully integrated DFE functionality, which includes carrier digital up/down conversion (CDUC and CDDC), crest factor reduction (CFR), digital predistortion (DPD), closed-loop gain control (CLGC) and voltage standing wave ratio (VSWR) monitor.
The CDUC feature of the ADRV9044 filters and places individual component carriers within the band of interest. The CDDC feature, with its eight parallel paths, processes each carrier individually before sending over the serial data interface.
The CDUC and CDDC reduce serialization/deserialization (SERDES) interface data rates in non-contiguous carrier configurations. This integration also reduces power compared to an equivalent FPGA based implementation.
The CFR engine of the ADRV9044 reduces the peak-to-average ratio (PAR) of the input signal, which enables higher efficiency transmit line ups while reducing the processing load on baseband processors.
The SoC also contains a fully integrated DPD engine for use in power amplifier linearization. The DPD enables the high-efficiency power amplifiers, which reduce the power consumption of base-station radios and the number of SERDES lanes interfacing with baseband processors. The DPD engine incorporates a dedicated long-term DPD (LT-DPD) block, which provides the support for GaN power amplifiers. The ADRV9044 tackles charge-trapping property of GaN power amplifiers with its LT-DPD block, hence improving the emissions and error vector magnitude (EVM). The SoC includes an ARM Cortex-A55 quad core processor to independently serve DPD, CLGC, and VSWR monitor features. The dedicated processor, together with the DPD engine, provides industry leading DPD performance.
The serial data interface consists of eight serializer and deserializer lanes. The interface supports the JESD204C standards, and both fixed and floating-point data formats are supported. The floatingpoint format allows internal automatic gain control (AGC) to be transparent to the baseband processor.
The ADRV9044 is powered directly from 0.8 V, 1.0 V, and 1.8 V regulators and is controlled through a standard SPI serial port. The comprehensive power-down modes are included to minimize the power consumption in normal use. The device is packaged in a 27 mm × 20 mm, 736-ball grid array.
APPLICATIONS
-
3G/4G/5G time division duplex (TDD)/frequency division duplex
(FDD) small cell, massive MIMO, and macro base stations
提问
在下面提交您的问题,我们将从 ADI 的知识库中给出最佳答案:
您可以在其他地方找到帮助
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ADRV9044
文档
筛查
1 应用
用户手册
1
产品技术资料帮助
ADI公司所提供的资料均视为准确、可靠。但本公司不为用户在应用过程中侵犯任何专利权或第三方权利承担任何责任。技术指标的修改不再另行通知。本公司既没有含蓄的允许,也不允许借用ADI公司的专利或专利权的名义。本文出现的商标和注册商标所有权分别属于相应的公司。
软件和型号相关生态系统
器件驱动器
API Device Drivers
Device Application Programming Interface (API) C code drivers provided as reference code allows the user to quickly configure the product using high-level function calls. The library acts as an abstraction layer between the application and the hardware. The API is developed in C99 to ensure agnostic processor and operating system integration. Customers can port this application layer code to their embedded systems/ Baseband Processor by integrating their platform-specific code base to the API HAL layer. To request this software package, go to the Software Request Form signed in with your MyAnalog account and under “Target Technology option - select “Wireless Communications" and choose processor/SOC as "ADRV9040 or ADRV9044" , select the check box as well and submit the form. You will receive an email notification with a link for software download.
正在寻找评估软件?您可以在这里找到
部分模型 | 产品周期 | 描述 | ||
---|---|---|---|---|
SPST、SPDT、SP3T、SP4T、SP5T、SP6T、SP8T1 |
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推荐新设计使用 |
0.1 GHz至6 GHz硅SP5T开关 |
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超低噪声稳压器1 |
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推荐新设计使用 |
具有超低噪声的18V/16A降压型Silent Switcher 3 |
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大规模MIMO接收器前端IC2 |
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推荐新设计使用 |
双通道,3.3 GHz至4.0 GHz,20 W接收器前端 |
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推荐新设计使用 |
双通道,3.3 GHz至4.0 GHz,20 W接收器前端 |
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多个输出降压调节器1 |
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推荐新设计使用 |
集成式三通道降压调节器电源解决方案 |
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时钟产生器件1 |
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推荐新设计使用 |
提供14路LVDS/HSTL输出的JESD204B/JESD204C时钟发生器 |
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时钟同步1 |
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推荐新设计使用 |
IEEE1588 第 2 版以及 1 pps 同步器和自适应时钟转换器 |
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增益模块2 |
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推荐新设计使用 |
30 MHz 至 6 GHz RF/IF 增益模块 |
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推荐新设计使用 |
30 MHz 至6 GHz RF/IF增益模块 |
The ADRV904x Evaluation GUI package contains the ACE installation and the ADRV9040 plugin required for evaluation. with ADRv904x evaluation board. For Software package including API , firmware binary etc , please fill the software request form above.
评估套件 2
ADS10-V1EBZ
ADS10-V1EBZ Evaluation Board
产品详情
资料
EVAL-ADRV904x
产品详情
介绍
ADRV904x 系列评估系统使客户能够评估 ADRV904x 设备,而无需开发定制硬件或软件。该系统由 ADRV904x 客户评估 (CE) 板和 ADS10-V1EBZ 主板组成,并配有配套的墙壁适配器电源。评估软件使用由 Analog Devices, Inc. 开发的分析、控制、评估 (ACE) 软件,并通过 ADRV904x 专用板插件进行扩展。该插件可以在通过以太网与 ADS10-V1EBZ 主板通信的 Windows 主机 PC 上与 ACE 一起运行。ADS10-V1EBZ 用作基带处理器,运行应用程序(ADRV904x 命令服务器),用于控制和与 ADRV904x 设备通信。
本文档还可作为 ADRV904x 配置器的快速入门指南,该配置器集成在 ACE 的 ADRV9040 板插件中。ADRV904x 配置器允许用户探索 ADRV904x 设备的各种配置,以达到所需的用例配置。ADRV904x 配置器还概述了所选配置的接收器 (Rx)、发射器 (Tx) 和观测接收器 (ORx) 数据路径的频率响应。
本用户指南详细介绍了安装 ADRV904x 评估软件、编程现有用例以及评估 ADRV904x 发射器、接收器和观测接收器数据路径所需的步骤。本用户指南的配置器部分允许用户生成新的用例并查看其对应的 ADRV904x 数据路径配置和过滤器图。请注意,随着配置器开发的进展和工具中添加的附加功能,该文档也会更新。