disk, which is often needed when using

optical encoders. At the same time, the

capacitive encoder provides equivalent

or superior accuracy compared to other

encoder technologies, with a typical

accuracy value of 0.2 degrees.

Another advantage of the capacitive

encoder is that resolution can be

adjusted dynamically, whereas optical

encoders are fixed such that changing

the resolution requires fitting a different

encoder. Adjustable resolution delivers

advantages in development, by allowing

engineers to make any changes to

prototypes quickly and easily, and

also aids production supply-chain

management by allowing a single stock-

keeping unit (SKU) to be used in multiple

motor controls of different resolutions.

The encoder housing is designed for

easy assembly and supports multiple

mounting options. In addition, multiple

sleeve sizes are provided to suit

commonly used motor shaft diameters.

Energy Savings and

Efficiency Gains

The AMT encoders have very low current

requirements, with some series drawing

less than 10mA of current at the highest

resolution. This corresponds to 0.2W in

a four-motor system operating at 5V.

Recall that optical and magnetic

encoders can draw considerably higher

current, thereby significantly increasing

overall power consumption in a multi-

motor system. Table 1 shows the power

consumed purely by the encoders

of a four-motor system such as a

drone or mobile robot, comparing the

performance of CUI AMT capacitive

encoders with optical and magnetic

alternatives.

Capacitive encoders are shown to

offer a superior energy-efficient

solution, and can give designers

more freedom to manage the limited

power budget in mobile and battery-

operated applications. Moreover, the

capacitive encoder’s operating current

is independent of the resolution setting,

which allows the encoder settings to

be optimized without compromising

application power consumption.

When paired to a brushless dc motor,

capacitive encoders also allow faster

and easier digital “zeroing” to align

the encoder U, V and W signals with

the rotor windings. To align an optical

encoder, the rotor is usually locked in

a known position and the code wheel

is physically aligned. The motor is then

back-driven while using an oscilloscope

to verify correct alignment of the

back-EMF and encoder zero-crossing

points. This is an iterative process that

can take 15 to 20 minutes, although

small errors may remain. These errors

prevent the motor running at maximum

efficiency, thereby wasting precious

battery energy. It is even possible that

the inability to optimize alignment may

force the engineer to over-specify the

motor to ensure the desired torque.

In contrast, digital zeroing by

programming the encoder using a

software application ensures perfect

alignment every time. The process takes

seconds to complete and eliminates

unit-to-unit variability. The motor is

energized to lock the rotor in the desired

position, and the encoder is set to zero

at this position using a single command.

No additional instruments are required.

By allowing accurate, repeatable

alignment, this technique ensures that

the motor is able to run smoothly at

optimum efficiency thereby delivering

best performance and maximizing

battery life in mobile applications.

Benefits Beyond Battery-

Operated Applications

Market demands for better performance

may provide enough encouragement

for designers of battery-operated

appliances to take advantage of

capacitive encoders to boost the

efficiency of next-generation drive

systems. On the other hand, the

emergence of new regulations

governing efficiency of electric motors

show that regulators are taking

a progressively tougher attitude

toward the efficiency of electric-

motor systems. These include the

EU’s latest IEC 60034-30-1 standard,

which has introduced a new Super

Premium Efficiency level for three-

phase induction motors. In the US,

the Department of Energy (DoE) will

bring new legislation into force in mid

2016 that both increases minimum

efficiency standards and includes types

of motors not previously covered.

The DoE’s analysis estimates that

more than 70% of the total potential

energy savings achievable through

the new legislation can be realized

through system-level savings such as

improving component efficiency and

using smaller motors where possible.

Capacitive encoders can help towards

using smaller motors, and allow

designers to reduce the power draw

of their entire systematic government

agencies continue to focus more

sharply on this area.

Conclusion

Affordable automation in the form of

small mobile robots and civil drones

could revolutionize activities such as

manufacturing, distribution and asset

management.

Low-power,

precision

capacitive

encoders can deliver valuable savings

in overall energy consumption for

these motor-rich mobile applications,

while also streamlining development

and manufacturing as well as reducing

maintenance overheads so helping to

reduce ownership costs. As emerging

government regulations indicate an

increasingly strict attitude to the energy

efficiency of motor systems, designers

could find even more incentives to

adopt this technology.

Encoder model

Type

Operating voltage

Current at highest reso-

lution

Power in 4-motor

system

AMT10

Capacitive

5V

6mA

0.12W

Competitor 1

Optical

5V

85mA

1.7W

Competitor 2

Magnetic

5V

160mA

3.2W

Table 1. Encoder power consumption comparison

New-Tech Magazine Europe l 46