ALS Applications in Portable Electronics

著者 ROHM Semiconductor

Convergence Promotions LLC の提供

High-resolution color handset displays render beautiful pictures, but they're power hungry. Using an ambient light sensor can result in a considerably longer battery life.

In portable electronic products, reducing power consumption to provide users with increased battery life is one of today's critical design considerations. The LCD (liquid crystal display) and its associated backlighting are among the more (and frequently the most) power-hungry loads in portable products. As a result, the use of an ALS (ambient light sensor) to optimize backlight LED operation under a variety of environmental lighting situations is increasing. At the same time, the preferred technology choices available to designers for sensing have shifted toward more integrated solutions.

How are ambient light sensors used?

Ambient light sensors are also called illuminance or illumination sensors, optical sensors, brightness sensors, or simply light sensors. One very important application for ALS technology is cell phones. Here, the ALS enables automatic control of display backlight brightness over a wide range of illumination conditions, from dark environments to direct sunlight. With ALS input, an MCU or baseband processor increases or decreases the display's brightness depending on the environment. This control dramatically improves visibility and reduces power consumption, since LCD backlighting can draw as much as 51 percent of the power in the input standby power mode. In addition, the ALS signal can be used to instruct the keypad LED driver to minimize keypad backlighting, reducing up to 30 percent of power consumed in the input standby power mode. In a bright environment, LED keypad brightness is reduced for minimal power consumption.

In addition to cell phones, ambient light sensors can be used in a variety of LCD-equipped portable products including PDAs, notebook PCs, digital cameras, video players, and GPS-based navigation systems. Any portable product with an LCD is a candidate for ALS technology to reduce power consumption. In automobiles, the use of LCDs is increasing for navigation, entertainment, and comfort systems, as well as control monitoring and dimming mirrors. Any product with an LCD that requires supplemental light for proper viewing can benefit from using an ALS to reduce power consumption and improve visibility under varying lighting conditions. This includes televisions and home appliances, especially those with increased electronic control and user-driven menus that require larger LCD panels.

The market research firm Databeans, Inc. estimates the current total available market for ambient light sensors to be seven percent of LED revenue, or roughly $327 million worldwide. According to Susie Inouye, research director and principal analyst at Databeans, "Due to the large number of feature-rich phone products that will drive demand, we expect this revenue to grow at a compound annual growth rate of 21 percent each year over the next five years to reach close to $860 million by 2014."

Types of ALS technologies

Today, designers have more technology choices for ambient light sensors, including photoelectric cells, photodiodes, phototransistors, and photo ICs. Each technology has advantages and disadvantages. One of the key criteria for selecting an ALS is its ability to detect wavelengths visible to the human eye in the 380 to 780 nm range. Figure 1 shows a summary of the advantages and disadvantages of available technologies.

While CdS (cadmium sulfide) photoelectric cells have the advantage of a response similar to that of the human eye, they contain cadmium, a prohibited RoHS (Restriction of Hazardous Substances) material which makes them unusable in the consumer market. In order to reduce the environmental impact of electronic equipment waste, as of July 2006, any product containing RoHS-restricted materials cannot be sold into certain markets.

Figure 1: Photo IC ALS technology addresses limitations of discrete photo cell, photodiode, and phototransistor products.

Figure 1: Photo IC ALS technology addresses limitations of discrete photo cell, photodiode, and phototransistor products.

Photodiodes have a relatively low dispersion between individual units, but a low output requires an external amplification circuit.

Phototransistors have easily obtainable output current but poor temperature characteristics and a large dispersion between individual units, requiring additional calibration steps in end products.

Photo ICs, also referred to as ALS ICs, are the newest technology, developed to address the shortcomings of other ALS approaches. In addition to the increased functions that are possible with integration (including amplification, logic control, and shutdown capability), the photodiode sensing has a relatively low dispersion. Both analog and digital photo ICs are available. Each has advantages depending on the application. The photo IC has integrated functionality that eliminates the need for additional circuitry, which takes up more board space and adds cost. As a result, many designers are making the transition to photo ICs from discrete devices.

Topology of ALS ICs

Both analog and digital ALS devices are silicon monolithic circuits with an integrated, light-sensitive, semiconductor photodiode (a PN junction that converts light into an electrical signal). Both technologies are available in small, surface-mount technology packages. Understanding the difference between analog and digital photo ICs is essential for selecting the proper ALS solution.

Figure 2: The typical analog ALS IC combines a photodiode with a current amplifier and control circuitry.

Figure 2: The typical analog ALS IC combines a photodiode with a current amplifier and control circuitry.

Analog ALS ICs

The analog ALS IC has an analog current output proportional to the incident light level. As shown in Figure 2, the IC combines the photodiode, signal amplification, and control logic. The current source output is typically converted to a voltage by means of a simple load resistor. This voltage output is typically applied to either the input of an ADC interface on an MCU (see Figure 3), or directly as an input to an LED driver IC equipped with auto-luminous control (see Figure 4).

Figure 3: The output of the analog ALS provides the control input to the system MCU.

Figure 3: The output of the analog ALS provides the control input to the system MCU.

Figure 4: When used in combination with an LED driver with auto-luminous control, the analog ALS output provides direct light level control.

Figure 4: When used in combination with an LED driver with auto-luminous control, the analog ALS output provides direct light level control.

Fundamental design advantages of the analog ALS include an output current proportional to the brightness of the environment, and spectrum sensitivity similar to that of the human eye.

Digital ALS ICs

The typical digital output ALS (see Figure 5) has a 16-bit digital I²C output. In addition to amplification for the photodiode, the IC's integrated ADC converts the photosensor's output to an I²C signal for direct connection to the I²C communication bus of an MCU or baseband processor. Figure 6 shows how the I²C interface simplifies the circuitry in an application by removing the need for an external ADC.

The digital ALS includes more integration than an analog ALS and can result in an overall cost savings, as well as space savings, on the PCB (printed circuit board).

Figure 5: A digital ALS integrates photodiode, amplification circuitry, an ADC, and the interface logic.

Figure 5: A digital ALS integrates photodiode, amplification circuitry, and ADC, and the interface logic.

Figure 6: In the digital ALS application, the controller communicates directly with both the ALS and the LED driver using an I2C

Figure 6: In the digital ALS application, the controller communicates directly with both the ALS and the LED driver using an I2C interface.

Selecting the right topology for the application

Deciding whether an analog or digital ALS is the most appropriate solution requires answering a few simple questions about the application.

  1. What communications bus/interface options are available? (Example: I²C or GPIO?)
  2. Is an ADC input available?
  3. What degree of lighting control is required?
  4. What environmental considerations are important?
    • Operating temperature range?
    • Variable light level/light sources?
  5. How important is power consumption?
In terms of power consumption, a digital ALS will likely draw more power in both the active mode (for example, 190 µA for the ROHM Semiconductor BH1750FVI) and power down mode (1.0 µA for the same digital ALS) due to the integration of the ADC when compared just to an analog ALS (97 µA and 0.4 µA, respectively for the ROHM Semiconductor BH1620FVC). However, the total power consumption may be comparable when a separate ADC + MCU or broadband controller is taken into account. In either case these values are quite low when compared to the power savings achieved by their ability to control the LED power consumption.

ROHM Semiconductor solutions

ROHM offers both analog and digital ALS ICs that have spectral sensitivity similar to the human eye. Both are offered in compact, surface-mount packages, the WSOF5 package (1.6 mm x 1.6 mm x 0.55 mm) and the WSOF6 package (3.0 mm x 1.6 mm x 0.7 mm).

All ROHM ambient light sensors operate over a temperature range of -40 to 85°C to ensure stable operation under extreme conditions. Figure 7(b) shows that ROHM's photodiode output is very stable regardless of light source, providing both reduced power consumption and an improved user experience.

Analog ALS solutions

ROHM Semiconductor ALS ICs have an output current proportional to light (current sourcing) with a measurement range of 0 to 100,000+ lux (lx). These ICs feature light sensing accuracy of ±15 percent based on ROHM's unique laser trimming technology that also ensures high output sensitivity. Each of these devices features an input voltage supply range from 2.4 to ~5.5 V. A resistor connected to the output current (Iout) pin converts the current output to a linear voltage from 0 V up to the supply voltage level for highly efficient component operation.

Figure 7: A competitor's sensor output.

Figure 7: A competitor's sensor output (a) produces different values depending on the light source but ROHM's ALS ICs (b) deliver stable output regardless of light source.

Figure 8 shows the relative spectral response of the ROHM Semiconductor analog ALS and luminosity versus output current. Multiple photodiodes with different junction depths provide a stable output with little variation between various light sources. Since wavelengths outside of the range of human vision, such as ultraviolet and infrared, may cause inaccurate light sensor readings, it is important to choose a light sensor that has spectral sensitivity similar to that of the human eye. While the data in Figure 8(a) is specifically for an analog ALS, this same performance is inherent in the digital designs, as well. In addition to an Iout proportional to the luminosity in lux, ROHM's analog ALS products have selectable high-gain, medium-gain, and low-gain modes, a proprietary function. These gain control modes allow for direct control of the internal amplifier gain via the GC1 and GC2 input pins. As shown in Figure 9, these three gain modes provide designers even greater design options for trading off performance versus power consumption.

Figure 8: Spectral sensitivity.

Figure 8: Spectral sensitivity (a) and luminosity versus IOUT (b) for the BH1603FVC demonstrate performance advantages that design engineers should consider when selecting an ALS.

GC2 GC1 Mode Function
0 0 Shutdown IOUT OUTPUT Disabled
0 1 H-Gain Mode 60 µA @ 100 lx
1 0 M-Gain Mode 10 µA @ 100 lx
1 1 L-Gain Mode 1 µA @ 100 lx
1:Connect to VCC 0: Connect to GND

Figure 9: Mode settings for ROHM Analog ALS ICs provide for shutdown and three levels of output current, offering improved design flexibility in performance versus power consumption.

Digital ALS solutions

ROHM was among the first companies to offer a digital light sensor, further demonstrating its leadership in ALS technology. Digital ALS ICs measure brightness and output in a 16-bit digital signal over an I²C bus interface, supporting FAST mode (400 KHz) and 1.8 V logic interface. The digital ALS ICs can detect a wide range of intensities (0 to ~65,535 lx). A unique internal shutdown function enables low current consumption.

A number of other features, described below, distinguish these digital photosensor ICs.

In the operating environment, it is important for a light sensor to generate a consistent output regardless of the light source. As shown in Figure 7(a), a competing solution outputs different values depending on the light source, which could cause the system to turn on the backlighting when it is not needed. This reduces battery life and potentially interferes with the end user's experience.

Figure 10: ICC current is independent of luminosity.

Figure 10: ICC current is independent of luminosity (a) for ROHM Semiconductor's digital ALS solutions as demonstrated by the performance of the BH1715FVC. At the same time, these units are compatible with a wide range of intensities (0 to ~65,535 lux) (b).

Excellent spectral response is another key characteristic of ROHM's digital ALS products. Figure 10 shows two electrical response graphs for the BH1715FVC. Figure 10(a) demonstrates that luminosity has a minimal impact on the digital light sensor's supply current (ICC) which improves power consumption. Figure 10(b) indicates luminosity versus output serial data measurement results for high- and low-resolution modes.

A comparison of the two resolution modes for improved lighting control is shown in Figure 11. The H-resolution mode has the highest resolution (1 lux increments) and is suitable for measuring very low lux levels, but it takes the longest time to measure a light sample. The advantage of operation in this mode is a higher accuracy light sample and superior optical noise rejection, since this capability improves with increased measurement time. Operation in H-Resolution mode eliminates optical noise at 50/60 Hz. An example of optical noise reduction with a fluctuating fluorescent light source output, demonstrating values stable within ±1 percent, is shown in Figure 12.

The L-Resolution mode samples in 4 lux increments and takes the shortest time to measure a light sample. Note that, in contrast to the analog ALS, different operating modes do not impact the power consumption in digital units.

Mode Measuring Time Typ. [ms] Minimum Resolution [lx] Features
H-Resolution 120 1 High resolution and Superior optical noise rejection characteristics (50/60 Hz)
L-Resolution 16 4 Measuring time and the resolution are well-balanced

Figure 11: ROHM Semiconductor's digital light sensors have high- and low-resolution modes.

Figure 12: Fluorescent light output fluctuates 25 percent.

Figure 12: Fluorescent light output fluctuates ±25 percent, synchronized with the AC supply (a). By detecting fluctuating light synchronized with the AC supply (50/60 Hz), the BH1715FVC digital ALS outputs values stable within ±1 percent (b).


Ambient light sensors are an important tool for enhancing performance in LED-backlighted LCD displays. ROHM offers both analog and digital units. In addition, ROHM offers design assistance in the form of ALS IC Evaluation Kits and optical simulation design support for all its ALS technologies.

  1. ROHM Semiconductor High-Performance Ambient Light Sensor IC Series Selection Catalog.
  2. Data sheets for ROHM Semiconductor BH1603FVC, BH1620FVC, BH1715FVC, BH1721FVC and BH1750FVI Ambient Light Sensors.

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