當(dāng)前位置:首頁 > 通信技術(shù) > 通信技術(shù)
[導(dǎo)讀]Abstract: This application note describes how to use of DS8500 HART modem for a process-control application. The article explains how to interface the DS8500 to a microcontroller and 4–20mA current l

Abstract: This application note describes how to use of DS8500 HART modem for a process-control application. The article explains how to interface the DS8500 to a microcontroller and 4–20mA current loop to ensure proper HART communication.

<-- ======================================================================= --><-- CONTENT: DB HTML --><-- ======================================================================= -->

Introduction

This application note introduces the DS8500 single-chip modem for HART® communication. This document should be used in conjunction with the DS8500 data sheet. While the specific requirements for an application can vary, the reference design shown here is a basic example for implementing a process-control circuit.

HART overview

Highway Addressable Remote Transducer (HART) communication is a commonly used mode of transmission for digital signals that are superimposed on the analog signal of a 4–20mA current loop. The HART protocol is based on the phase continuous frequency shift keying (FSK) technique. Bit 0 is modulated to a 2200Hz sinusoidal signal, and bit 1 is modulated to a 1200Hz sinusoidal signal with a baud rate of 1200bps. These two frequencies can easily be superimposed on the analog current-loop signal, which is in the range of DC to 10Hz, without affecting either signal. This unique nature of the HART protocol enables simultaneous analog and digital communication on the same wire.

DS8500 HART modem

The DS8500 is a HART modem that provides phase-continuous FSK modulation and demodulation for process-control applications. This device is a feature-rich low-power modem that satisfies the physical layer specifications set by the HART Communication Foundation. The DS8500 has many features that allow the user to easily and effectively design a process-control system that requires a HART modem.
  • Reliable signal detection
  • Few external components
  • Sinusoidal output signal
  • Low power consumption
  • Standard 3.6864MHz crystal
An internal, digital-signal-processing technique enables reliable FSK_IN signal detection; very few external components are required to separate a HART signal from the noise. FSK_OUT is a sinusoidal signal that provides the lowest harmonic distortion to the system.

Figure 1 shows a top-level block diagram of the DS8500 in an intelligent process transmitter. The design highlights the interface between the HART modem and other external ICs.


Figure 1. An intelligent process transmitter features the DS8500 HART modem communicating with a system microcontroller.

Basic DS8500 operation

Clock

The DS8500 requires a 3.6864MHz clock as an input source with ±1% accuracy to guarantee proper operation. Figure 2 shows a typical circuit for clock source. When XCEN is set high, the user can drive an external clock directly onto the XTAL1 pin. If an external 3.6864MHz crystal is desired, XCEN should be set low and the crystal needs to be connected between XTAL1 and XTAL2.


Figure 2. Crystal connection for the DS8500.

Microcontroller interface

The HART protocol requires signals to be communicated in a specific 11-bit UART format: a start bit, 8 data bits, one parity bit, and a stop bit. The modulator and the demodulator blocks of the DS8500 need to interface with a microcontroller UART to satisfy the protocol requirement.

In demodulator mode, the DS8500 expects a valid UART start signal to synchronize the data communication. The interface between the HART modem and the microcontroller is also shown in Figure 1. Referring back to Figure 1, the microcontroller must contain the HART software stack required for communication. D_IN is the digital-signal data input to the DS8500 which will modulate it to an FSK_OUT signal. D_OUT is the digital-signal data output from the DS8500 that has been demodulated from an FSK_IN signal. RTS receives the microcontroller's request to initiate the demodulate (Rx) or modulate (Tx) mode of the modem.

Active-low RST provides a reset to the DS8500 and ensures that all the internal registers and filters start from a known default value. OCD is a carrier-detect signal that determines an FSK signal with a valid amplitude at the input of the demodulator. A logic high on OCD indicates that the FSK_IN signal amplitude is greater than 120mV; a logic low indicates that the FSK_IN signal amplitude is less than 80mV or that there is no carrier signal. Optionally, the microcontroller can provide a 3.6864MHz clock to the DS8500.

Modulator waveform

Figure 3 shows the DS8500 in modulate mode where D_IN is the input to the modem and FSK_OUT is the modulated output. The data is provided in an 11-bit UART format.


Figure 3. Modulator waveform.

Demodulator waveform

Figure 4 shows the DS8500 in demodulate mode where FSK_IN is the input to the modem and D_OUT is the output to the UART.


Figure 4. Demodulator waveform.

External filters

Due to the digital nature of DS8500 and its built-in digital filters, the number of external passive components required for modem operation is greatly reduced.

Figure 5 shows the few external components needed on the receive and transmit sides. The demodulator in DS8500 requires just a simple lowpass filter with a cutoff frequency of 10kHz (R3, C3) and a highpass filter with a cutoff frequency of 480Hz (C2, R2) to separate the HART signal from the analog signal and interferences. The resistor-divider formed by R1 and R2 provides an input bias voltage of VREF/2 to the DS8500's receive-side circuitry. The RC values shown below are just an example; a different set of RC values can be used, if the cutoff frequencies of lowpass and highpass filters are met.

Together these external components and the internal filters reject the low-frequency analog signals and prevent them from compromising digital reception. In addition, high-frequency components are also attenuated to prevent interference above the HART extended frequency band.


Figure 5. Receive/transmit side external components.

DS8500 as slave or master

The DS8500 modem can be used in either the slave side or the master side of HART communication. Typically, on the slave side the HART modem is part of the intelligent process transmitter unit; on the master side the modem is part of the HART master modem cable that connects the central control unit or the handheld unit to the current loop. Figure 6 shows the interface between master, slave, and current loop.


Figure 6. HART devices connections.

Figure 7 shows a HART slave using DS8500 circuitry and the top-level blocks necessary for an intelligent process transmitter. A temperature process transmitter serves as an example for this circuit. The sensor on the process transmitter measures the system temperature in current or voltage and then passes the data to the ADC. The ADC, in turn, converts these analog signals to digital equivalents for the microcontroller to process. The microcontroller provides remote memory along with computation power. The microcontroller typically hosts the HART stack and is responsible for the protocol implementation; it also processes the digital data from the HART modem. Microcontroller capabilities can also be used for sensor calibration, linearization and signal conditioning. The DAC is primarily responsible for driving the current loop.


Figure 7. DS8500 on the slave side of HART communication. D_IN receives data from the microcontroller's UART. D_OUT transmits data to the UART. Active-low RST is the DS8500 reset. OCD is a carrier-detect signal that determines a FSK signal with a valid amplitude at the input of the demodulator.

On the master side, the DS8500 can be part of the master modem that resides either on the central control unit or the handheld HART communicator. Figure 8 shows the master-side configuration. In this case, the DS8500 communicates to the PC through an RS-232 serial port. The HART protocol is usually supported by software that can be installed on the computer.


Figure 8. DS8500 on the master side of HART communication. D_IN receives data from the microcontroller's UART. D_OUT transmits data to the UART. Active-low RST is the DS8500 reset. OCD is a carrier-detect signal that determines a FSK signal with a valid amplitude at the input of the demodulator.



Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.
本站聲明: 本文章由作者或相關(guān)機構(gòu)授權(quán)發(fā)布,目的在于傳遞更多信息,并不代表本站贊同其觀點,本站亦不保證或承諾內(nèi)容真實性等。需要轉(zhuǎn)載請聯(lián)系該專欄作者,如若文章內(nèi)容侵犯您的權(quán)益,請及時聯(lián)系本站刪除。
換一批
延伸閱讀

9月2日消息,不造車的華為或?qū)⒋呱龈蟮莫毥谦F公司,隨著阿維塔和賽力斯的入局,華為引望愈發(fā)顯得引人矚目。

關(guān)鍵字: 阿維塔 塞力斯 華為

加利福尼亞州圣克拉拉縣2024年8月30日 /美通社/ -- 數(shù)字化轉(zhuǎn)型技術(shù)解決方案公司Trianz今天宣布,該公司與Amazon Web Services (AWS)簽訂了...

關(guān)鍵字: AWS AN BSP 數(shù)字化

倫敦2024年8月29日 /美通社/ -- 英國汽車技術(shù)公司SODA.Auto推出其旗艦產(chǎn)品SODA V,這是全球首款涵蓋汽車工程師從創(chuàng)意到認(rèn)證的所有需求的工具,可用于創(chuàng)建軟件定義汽車。 SODA V工具的開發(fā)耗時1.5...

關(guān)鍵字: 汽車 人工智能 智能驅(qū)動 BSP

北京2024年8月28日 /美通社/ -- 越來越多用戶希望企業(yè)業(yè)務(wù)能7×24不間斷運行,同時企業(yè)卻面臨越來越多業(yè)務(wù)中斷的風(fēng)險,如企業(yè)系統(tǒng)復(fù)雜性的增加,頻繁的功能更新和發(fā)布等。如何確保業(yè)務(wù)連續(xù)性,提升韌性,成...

關(guān)鍵字: 亞馬遜 解密 控制平面 BSP

8月30日消息,據(jù)媒體報道,騰訊和網(wǎng)易近期正在縮減他們對日本游戲市場的投資。

關(guān)鍵字: 騰訊 編碼器 CPU

8月28日消息,今天上午,2024中國國際大數(shù)據(jù)產(chǎn)業(yè)博覽會開幕式在貴陽舉行,華為董事、質(zhì)量流程IT總裁陶景文發(fā)表了演講。

關(guān)鍵字: 華為 12nm EDA 半導(dǎo)體

8月28日消息,在2024中國國際大數(shù)據(jù)產(chǎn)業(yè)博覽會上,華為常務(wù)董事、華為云CEO張平安發(fā)表演講稱,數(shù)字世界的話語權(quán)最終是由生態(tài)的繁榮決定的。

關(guān)鍵字: 華為 12nm 手機 衛(wèi)星通信

要點: 有效應(yīng)對環(huán)境變化,經(jīng)營業(yè)績穩(wěn)中有升 落實提質(zhì)增效舉措,毛利潤率延續(xù)升勢 戰(zhàn)略布局成效顯著,戰(zhàn)新業(yè)務(wù)引領(lǐng)增長 以科技創(chuàng)新為引領(lǐng),提升企業(yè)核心競爭力 堅持高質(zhì)量發(fā)展策略,塑強核心競爭優(yōu)勢...

關(guān)鍵字: 通信 BSP 電信運營商 數(shù)字經(jīng)濟

北京2024年8月27日 /美通社/ -- 8月21日,由中央廣播電視總臺與中國電影電視技術(shù)學(xué)會聯(lián)合牽頭組建的NVI技術(shù)創(chuàng)新聯(lián)盟在BIRTV2024超高清全產(chǎn)業(yè)鏈發(fā)展研討會上宣布正式成立。 活動現(xiàn)場 NVI技術(shù)創(chuàng)新聯(lián)...

關(guān)鍵字: VI 傳輸協(xié)議 音頻 BSP

北京2024年8月27日 /美通社/ -- 在8月23日舉辦的2024年長三角生態(tài)綠色一體化發(fā)展示范區(qū)聯(lián)合招商會上,軟通動力信息技術(shù)(集團)股份有限公司(以下簡稱"軟通動力")與長三角投資(上海)有限...

關(guān)鍵字: BSP 信息技術(shù)
關(guān)閉
關(guān)閉