37款傳感器與執行器的提法,在網絡上廣泛流傳,其實Arduino能夠兼容的傳感器模塊肯定是不止這37種的。鑒於本人手頭積累了一些傳感器和執行器模塊,依照實踐出真知(一定要動手做)的理念,以學習和交流為目的,這里准備逐一動手嘗試系列實驗,不管成功(程序走通)與否,都會記錄下來---小小的進步或是搞不掂的問題,希望能夠拋磚引玉。
【Arduino】168種傳感器模塊系列實驗(資料+代碼+圖形+仿真)
實驗六十七: GY-68 BMP180 新款 BOSCH溫度模塊氣壓傳感器(替代BMP085)
BMP180
是博世Sensortec的新數字氣壓傳感器,具有很高的性能,使應用先進的移動設備,如智能手機、平板電腦和體育設備。它遵循了BMP085帶來了很多改進,像小尺寸和數字接口的擴張。超低功耗降至3μA使BMP180節電為您的移動設備的領導者。BMP180也是傑出的非常穩定的性能,最好有獨立電源供電。BMP180是一款高精度、小體積、超低能耗的壓力傳感器,可以應用在移動設備中它的性能卓越,絕對精度最低可以達到0.03hPa,並且耗電極低,只有3μA。BMP180采用強大的8-pin陶瓷無引線芯片承載(LCC)超薄封裝,可以通過I2C總線直接與各種微處理器相連。
BMP180主要特點
壓力范圍:300~1100hPa(海拔9000米~-500米)
電源電壓:1.8V~3.6V(VDDA),1.62V~3.6V(VDDD) VIN需要5V
LCC8封裝:無鉛陶瓷載體封裝(LCC)
低功耗:5μA,在標准模式
高精度:低功耗模式下,分辨率為0.06hPa(0.5米)
高線性模式下,分辨率為0.03hPa(0.25米)
含溫度輸出
I2C接口
溫度補償
無鉛,符合RoHS規范
MSL 1反應時間:7.5ms
待機電流:0.1μA
無需外部時鍾電路
BMP180技術數據
壓力范圍300……1100 hPa
均方根噪聲中表達壓力0.06 hPa typ。(超低功耗模式)
0.02 hPa typ。(超高分辨率模式)
均方根噪聲中表達高度0.5 m,typ。(超低功耗模式)
0.17米,typ。(超高分辨率模式)
相對精度的壓力
VDD = 3.3 v 950……1050 hPa / hPa±0.12
@ 25°C / m±1.0
700年……900 hPa / hPa±0.12
25…40°C / m±1.0
絕對精度
p = 300…1100 hpa
(溫度= 0…+ 65°C,VDD = 3.3。-4.0 V)壓力:……+ 2.0 hPa
溫度:±1°C,typ。
平均電流消耗(1 Hz刷新率數據)
峰值電流3μA典型(超低功耗模式)
32μA,典型的(高級模式)
650μA,典型的
待機電流1.62……3.6 V
電源電壓vddio 1.62……3.6 V
電源電壓vdd 1.8……3.6 V
操作溫度。
范圍全面准確”40…+ 85°C
0…+ 65°C
conv壓力。5毫秒,典型的(標准模式)
I2C傳輸速率3.4 MHz,馬克斯。
BMP180典型應用
GPS精准導航(航位推算,上下橋檢測等)
室內室外導航
休閑、體育和醫療健康等監測
天氣預報
垂直速度指示(上升/下沉速度)
風扇功率控制
體育設備,如高度剖面
BMP180氣壓模塊是一款高精度、小體積、低能耗的壓力傳感器,可以應用在移動設備中,它的性能卓越,絕對精度最低可以達到0.03hPa,並且耗電極低,只有3μA。BMP180采用強大的8-pin陶瓷無引線芯片承載(LCC)超薄封裝,可以通過I2C總線直接與各種微處理器相連。
特性曲線
模塊電原理圖
需要用的 “SFE_BMP180” 庫文件如下
SFE_BMP180.h
/*
【Arduino】66種傳感器模塊系列實驗(68)
實驗六十八:BMP180 新款 BOSCH溫度模塊氣壓傳感器(代替BMP085)
SFE_BMP180.h
*/
#ifndef SFE_BMP180_h
#define SFE_BMP180_h
#if defined(ARDUINO) && ARDUINO >= 100
#include "Arduino.h"
#else
#include "WProgram.h"
#endif
class SFE_BMP180
{
public:
SFE_BMP180();
char begin();
shorted?)
char startTemperature(void);
char getTemperature(double &T);
startTemperature command
char startPressure(char oversampling);
char getPressure(double &P, double &T);
startPressure command
double sealevel(double P, double A);
weather data)
double altitude(double P, double P0);
sea-level, runway, etc.)
char getError(void);
private:
char readInt(char address, int16_t &value);
char readUInt(char address, uint16_t &value);
char readBytes(unsigned char *values, char length);
char writeBytes(unsigned char *values, char length);
subsequent registers)
int16_t AC1,AC2,AC3,VB1,VB2,MB,MC,MD;
uint16_t AC4,AC5,AC6;
double c5,c6,mc,md,x0,x1,x2,y0,y1,y2,p0,p1,p2;
char _error;
};
#define BMP180_ADDR 0x77
#define BMP180_REG_CONTROL 0xF4
#define BMP180_REG_RESULT 0xF6
#define BMP180_COMMAND_TEMPERATURE 0x2E
#define BMP180_COMMAND_PRESSURE0 0x34
#define BMP180_COMMAND_PRESSURE1 0x74
#define BMP180_COMMAND_PRESSURE2 0xB4
#define BMP180_COMMAND_PRESSURE3 0xF4
SFE_BMP180.cp
/*
【Arduino】66種傳感器模塊系列實驗(68)
實驗六十八:BMP180 新款 BOSCH溫度模塊氣壓傳感器(代替BMP085)
SFE_BMP180.cp
*/
#include <SFE_BMP180.h>
#include <Wire.h>
#include <stdio.h>
#include <math.h>
SFE_BMP180::SFE_BMP180()
{
}
char SFE_BMP180::begin()
{
double c3,c4,b1;
Wire.begin();
if (readInt(0xAA,AC1) &&
readInt(0xAC,AC2) &&
readInt(0xAE,AC3) &&
readUInt(0xB0,AC4) &&
readUInt(0xB2,AC5) &&
readUInt(0xB4,AC6) &&
readInt(0xB6,VB1) &&
readInt(0xB8,VB2) &&
readInt(0xBA,MB) &&
readInt(0xBC,MC) &&
readInt(0xBE,MD))
{
AC6 = 23153;
Calcs.pdf
25671; AC6 = 18974;
c3 = 160.0 * pow(2,-15) * AC3;
c4 = pow(10,-3) * pow(2,-15) * AC4;
b1 = pow(160,2) * pow(2,-30) * VB1;
c5 = (pow(2,-15) / 160) * AC5;
c6 = AC6;
mc = (pow(2,11) / pow(160,2)) * MC;
md = MD / 160.0;
x0 = AC1;
x1 = 160.0 * pow(2,-13) * AC2;
x2 = pow(160,2) * pow(2,-25) * VB2;
y0 = c4 * pow(2,15);
y1 = c4 * c3;
y2 = c4 * b1;
p0 = (3791.0 - 8.0) / 1600.0;
p1 = 1.0 - 7357.0 * pow(2,-20);
p2 = 3038.0 * 100.0 * pow(2,-36);
return(1);
}
else
{
return(0);
}
}
char SFE_BMP180::readInt(char address, int16_t &value)
{
unsigned char data[2];
data[0] = address;
if (readBytes(data,2))
{
value = (int16_t)((data[0]<<8)|data[1]);
negative
return(1);
}
value = 0;
return(0);
}
char SFE_BMP180::readUInt(char address, uint16_t &value)
{
unsigned char data[2];
data[0] = address;
if (readBytes(data,2))
{
value = (((uint16_t)data[0]<<8)|(uint16_t)data[1]);
return(1);
}
value = 0;
return(0);
}
char SFE_BMP180::readBytes(unsigned char *values, char length)
{
char x;
Wire.beginTransmission(BMP180_ADDR);
Wire.write(values[0]);
_error = Wire.endTransmission();
if (_error == 0)
{
Wire.requestFrom(BMP180_ADDR,length);
while(Wire.available() != length) ;
for(x=0;x<length;x++)
{
values[x] = Wire.read();
}
return(1);
}
return(0);
}
char SFE_BMP180::writeBytes(unsigned char *values, char length)
{
char x;
Wire.beginTransmission(BMP180_ADDR);
Wire.write(values,length);
_error = Wire.endTransmission();
if (_error == 0)
return(1);
else
return(0);
}
char SFE_BMP180::startTemperature(void)
{
unsigned char data[2], result;
data[0] = BMP180_REG_CONTROL;
data[1] = BMP180_COMMAND_TEMPERATURE;
result = writeBytes(data, 2);
if (result)
return(5);
else
return(0);
}
char SFE_BMP180::getTemperature(double &T)
{
unsigned char data[2];
char result;
double tu, a;
data[0] = BMP180_REG_RESULT;
result = readBytes(data, 2);
if (result)
{
tu = (data[0] * 256.0) + data[1];
a = c5 * (tu - c6);
T = a + (mc / (a + md));
}
return(result);
}
char SFE_BMP180::startPressure(char oversampling)
{
unsigned char data[2], result, delay;
data[0] = BMP180_REG_CONTROL;
switch (oversampling)
{
case 0:
data[1] = BMP180_COMMAND_PRESSURE0;
delay = 5;
break;
case 1:
data[1] = BMP180_COMMAND_PRESSURE1;
delay = 8;
break;
case 2:
data[1] = BMP180_COMMAND_PRESSURE2;
delay = 14;
break;
case 3:
data[1] = BMP180_COMMAND_PRESSURE3;
delay = 26;
break;
default:
data[1] = BMP180_COMMAND_PRESSURE0;
delay = 5;
break;
}
result = writeBytes(data, 2);
if (result)
return(delay);
else
return(0);
}
char SFE_BMP180::getPressure(double &P, double &T)
sealevel().
{
unsigned char data[3];
char result;
double pu,s,x,y,z;
data[0] = BMP180_REG_RESULT;
result = readBytes(data, 3);
if (result)
{
pu = (data[0] * 256.0) + data[1] + (data[2]/256.0);
s = T - 25.0;
x = (x2 * pow(s,2)) + (x1 * s) + x0;
y = (y2 * pow(s,2)) + (y1 * s) + y0;
z = (pu - x) / y;
P = (p2 * pow(z,2)) + (p1 * z) + p0;
}
return(result);
}
double SFE_BMP180::sealevel(double P, double A)
{
return(P/pow(1-(A/44330.0),5.255));
}
double SFE_BMP180::altitude(double P, double P0)
{
return(44330.0*(1-pow(P/P0,1/5.255)));
}
char SFE_BMP180::getError(void)
{
return(_error);
}
模塊接線方式
1.先連接芯片與單片機(通過I2C接口),按照如下方式連接
5V—VIN
GND–GND
A5—SCL
A4—SDA
2.然后UNO通過usb與PC電腦連接
3.拷貝后面的代碼燒錄進Arduino
實驗開源代碼
/*
【Arduino】168種傳感器模塊系列實驗(67)
實驗六十七:BMP180 新款 BOSCH溫度模塊氣壓傳感器(代替BMP085)
程序之一
*/
#include <SFE_BMP180.h>
SFE_BMP180 AirPresure;
char presureDelayTime;
double presureP, presureT;
void setup() {
Serial.begin(9600);
AirPresure.begin();
}
void loop()
{
presureDelayTime = AirPresure.startPressure(3);
if (presureDelayTime != 0)
{
delay(presureDelayTime);
presureDelayTime = AirPresure.getPressure(presureP, presureT);
if (presureDelayTime != 0)
{
Serial.print("Current Preasure: ");
Serial.print(presureP);
Serial.println(" bar");
Serial.print(presureP);
Serial.print(" bar is");
Serial.print(presureP / 1000.0);
Serial.println(" atm");
}
else
{
Serial.println("ERROR");
}
}
else
{
Serial.println("ERROR");
}
delay(1000);
}
/* 【Arduino】168種傳感器模塊系列實驗(67) 實驗六十七:BMP180 新款 BOSCH溫度模塊氣壓傳感器(代替BMP085) 程序之二,氣溫、氣壓與海拔值可以調整並校准 */ #include <Wire.h> #define BMP180ADD 0x77 unsigned char OSS; int ac1; int ac2; int ac3; unsigned int ac4; unsigned int ac5; unsigned int ac6; int b1; int b2; int mb; int mc; int md; float temperature; double pressure; double pressure2; long b5; double altitude; void setup() { Serial.begin(9600); Wire.begin(); OSS = 2; BMP180start(); } void loop() { calculate(); show(); delay(1000); } void calculate() { temperature = bmp180GetTemperature(bmp180ReadUT()); temperature = temperature*0.0137; pressure = bmp180GetPressure(bmp180ReadUP()); pressure2 = pressure/115325; pressure2 = pow(pressure2,0.29029496); altitude = 39*(1+pressure2); } void show() { Serial.print("氣溫: "); Serial.print(temperature, 1); Serial.println(" C"); Serial.print("氣壓: "); Serial.print(pressure, 0); Serial.println(" Pa"); Serial.print("海拔:"); Serial.print(altitude); Serial.println("m"); } void BMP180start() { ac1 = bmp180ReadDate(0xAA); ac2 = bmp180ReadDate(0xAC); ac3 = bmp180ReadDate(0xAE); ac4 = bmp180ReadDate(0xB0); ac5 = bmp180ReadDate(0xB2); ac6 = bmp180ReadDate(0xB4); b1 = bmp180ReadDate(0xB6); b2 = bmp180ReadDate(0xB8); mb = bmp180ReadDate(0xBA); mc = bmp180ReadDate(0xBC); md = bmp180ReadDate(0xBE); } short bmp180GetTemperature(unsigned int ut) { long x1, x2; x1 = (((long)ut - (long)ac6)*(long)ac5) >> 15; x2 = ((long)mc << 11)/(x1 + md); b5 = x1 + x2; return ((b5 + 8)>>4); } long bmp180GetPressure(unsigned long up) { long x1, x2, x3, b3, b6, p; unsigned long b4, b7; b6 = b5 - 4000; x1 = (b2 * (b6 * b6)>>12)>>11; x2 = (ac2 * b6)>>11; x3 = x1 + x2; b3 = (((((long)ac1)*4 + x3)<<OSS) + 2)>>2; x1 = (ac3 * b6)>>13; x2 = (b1 * ((b6 * b6)>>12))>>16; x3 = ((x1 + x2) + 2)>>2; b4 = (ac4 * (unsigned long)(x3 + 32768))>>15; b7 = ((unsigned long)(up - b3) * (50000>>OSS)); if (b7 < 0x80000000) p = (b7<<1)/b4; else p = (b7/b4)<<1; x1 = (p>>8) * (p>>8); x1 = (x1 * 3038)>>16; x2 = (-7357 * p)>>16; p += (x1 + x2 + 3791)>>4; return p; } int bmp180Read(unsigned char address) { unsigned char data; Wire.beginTransmission(BMP180ADD); Wire.write(address); Wire.endTransmission(); Wire.requestFrom(BMP180ADD, 1); while(!Wire.available()); return Wire.read(); } int bmp180ReadDate(unsigned char address) { unsigned char msb, lsb; Wire.beginTransmission(BMP180ADD); Wire.write(address); Wire.endTransmission(); Wire.requestFrom(BMP180ADD, 2); while(Wire.available()<2); msb = Wire.read(); lsb = Wire.read(); return (int) msb<<8 | lsb; } unsigned int bmp180ReadUT() { unsigned int ut; Wire.beginTransmission(BMP180ADD); Wire.write(0xF4); Wire.write(0x2E); Wire.endTransmission(); delay(5); ut = bmp180ReadDate(0xF6); return ut; } unsigned long bmp180ReadUP() { unsigned char msb, lsb, xlsb; unsigned long up = 0; Wire.beginTransmission(BMP180ADD); Wire.write(0xF4); Wire.write(0x34 + (OSS<<6)); Wire.endTransmission(); delay(2 + (3<<OSS)); Wire.beginTransmission(BMP180ADD); Wire.write(0xF6); Wire.endTransmission(); Wire.requestFrom(BMP180ADD, 3); while(Wire.available() < 3); msb = Wire.read(); lsb = Wire.read(); xlsb = Wire.read(); up = (((unsigned long) msb << 16) | ((unsigned long) lsb << 8) | (unsigned long) xlsb) >> (8-OSS);//16 to 19 bit return up; }
/*
【Arduino】168種傳感器模塊系列實驗(67)
實驗六十七:BMP180 新款 BOSCH溫度模塊氣壓傳感器(代替BMP085)
程序之三,溫度、實時氣壓、已知海拔計算的海平面的氣壓、已知海平面氣壓計算的高度
只是算法有點爛,做做實驗而已
*/
#include <SFE_BMP180.h>
#include <Wire.h>
SFE_BMP180 pressure;
#define ALTITUDE 255.0
unsigned long gpstimes;
void setup()
{
Serial.begin(9600);
pressure.begin();
}
void loop()
{
gpstimes=millis();
char status;
double T,P,p0,a;
status = pressure.startTemperature();
delay(status);
status = pressure.getTemperature(T);
delay(status);
Serial.print("temperature: ");
Serial.print(T,2);
Serial.println(" deg C, ");
status = pressure.startPressure(3);
delay(status);
status = pressure.getPressure(P,T);
// Print out the measurement:
Serial.print("absolute pressure A: ");
Serial.print(P,2);
Serial.println(" mb, ");
p0=1013.2;
a = pressure.altitude(P,p0);
Serial.print("computed altitude A: ");
Serial.print(a,0);
Serial.println(" meters, ");
T=25.00;
status = pressure.getPressure(P,T);
Serial.print("absolute pressure B: ");
Serial.print(P,2);
Serial.println(" mb, ");
p0=1013.2;
a = pressure.altitude(P,p0);
Serial.print("computed altitude B: ");
Serial.print(a,0);
Serial.println(" meters, ");
gpstimes=millis()-gpstimes;
Serial.print("gpstimes=");
Serial.println(gpstimes);
Serial.println();
delay(2000);
}
