High intensity discharge (HID) lighting, by definition, has high levels of electrical discharge, to create an electrical arc in the bulb, which emits light. Supplying the power to create, drive, and sustain this arc reliably is no easy feat. The device that does this is called a ballast. It is a complex circuit made up of many components to accomplish specific tasks. To sum it up, one could say that the ballast is a “power controller” in an HID system.
How It Works
HID systems use an electrical arc, which requires very high voltage to initially create, and then high voltage to maintain as well. This is why an HID bulb won’t work without the ballast- it takes a lot more than 12V to create an electrical arc of light.
First, power is input into the ballast. Often, ballast input wires have modules to smooth the power signal coming in, and provide extra resistance to the vehicle’s circuit. These are generally known as CANBUS modules. Once there is a good, constant, smooth, reliable input power, the power goes to the primary circuit of the ballast.
The main controller circuit of the ballast has two main functions: it inverts the power into an AC signal, and controls the voltage output as the bulb operates. It does this by sensing resistance in the bulb, thousands of times per second, and adjusting the output.
To get things started, though, a high-voltage pulse must be transmitted to the HID bulb to initially create an electrical arc. This is accomplished with the igniter, which is a capacitor device that can quickly discharge a high amount of power. From there, the controller circuit takes over, and slowly lowers the power as the bulb warms up, and then maintains continuous operation.
All ballasts have an efficiency, measured as the power coming out divided by the power going in. If you send 10W to a device and it outputs 9W, it would be 90% efficient. The rest of the power is lost as heat, which is a reason ballasts might get warm during operation. No electrical device is perfectly efficient.
The best automotive HID ballasts can reach efficiency levels of nearly 90%, with ASIC controllers and high-quality components. The average mid-range ballast is likely around 75-80% efficient, and your “eBay Special” Rs 1500 per kit ballast will be around 60%. The worst ballast Eufonious Electronics has measured was only 52% efficient. Yikes!
Ratings – Truth In Advertising
Most ballasts are rated at 35W, or 35 watts of power. However, this is quite misleading- most suppliers will tell you the input power rating, or how much power is going into the ballast when it’s hooked up. Your 35W cheap ballast is probably drawing 35W input, not outputting 35W!
A cheap, low-performance ballast will light up your HIDs just fine, but it might be only 60% efficient, meaning that your “35W” rated ballast may only be outputting 21 watts! That will result in nearly half the potential brightness!
Good, quality HID ballasts provide a true 35W of output power. UGLARE slim ballasts actually output 38 watts! By just switching your ballasts to high-quality ballasts, you’ll often improve the performance of your HIDs.
Individual Components in Ballasts
Power Input Connector
By industry standard, all ballasts use a 9006-size input wire. Your HID kit should come with an adapter to convert your socket size, such as H11, so you can plug it into the ballast connector. These connectors should be fully waterproof. The connector may also have an LED built-in, just for convenience, which comes on anytime the ballast is getting power.
The heart of the ballast is an integrated circuit which serves two functions. First, the power must be inverted to provide alternating current (AC) to the bulb. There are ballasts that do not do this, called DC, and you can begin to see why DC is usually much cheaper- you don’t even need the inverter part of the circuit! However, DC HIDs are very poor in performance and reliability.
The most expensive part of the ballast is the controller chip, which is found in all digital ballasts. This has the computing power necessary to constantly measure the resistance in the bulb, based on the electrical arc of light, and then calculate and output correct power to maintain that arc, so that a constant beam is produced, without any flickering or dimming. This is all dependent on many variables, including the quality and age of the bulbs, the physical temperature, etc.
The most important time for the controller chip performs is when the HIDs are turned on, right after the bulbs ignite. This is called the “warm up.” As the bulb phyiscally warms up, the controller chip must quickly provide appropriate power and quickly adjust output as the bulb warms up. How quickly an HID bulb warms up, and how uniform the light is, depends in part on how quickly the ballast can control this.
If it takes more than a second or two for your HIDs to reach near-full brightness, or the color keeps changing back and forth, you probably have a cheaper controller circuit. These deficiencies will lead to a lower bulb life, as the bulb is stressed more than it would be with a better-controlled power supply.
The best digital ballasts use application-specific integrated circuits, or ASIC chips. These chips have been designed specifically to handle the task of controlling HID bulbs, so they are much better at accomplishing the task. Most digital ballasts use generic integrated circuits, which are much less expensive.
The final component along the line is the igniter, which is made up of multiple capacitors, and designed to charge and discharge quickly in order to initially provide the HID bulb with enough voltage to create an arc. It only takes around 70 volts AC to maintain an arc, but when you start it, you need very high voltage. Most igniters are rated to provide 23,000 volts, or 23kV. Some cheaper ballasts use smaller capacitors, which are cheaper, and provide only 20kV.
The primary capacitor in the igniter is also the widest component in the whole system, so the igniter is usually moved outside of the main housing, which allows the main housing to be much thinner, or “slim.” There is no difference in the performance or output when it is moved outside of the housing.
The output connectors are usually AMP-type standard connectors. These wires should be shielded to reduce electrical interference, but otherwise, they are quite straigh forward. Many OEM ballasts have a D2 connector to plug directly into a factory D2-size HID bulb, but there is no difference in quality between the connector types.
Housing and Potting
The circuitry is all housed in a case, which is usually aluminum. Very inexpensive ballasts will have plastic cases. The ballast generates some heat during operation, and aluminum ensures good heat dissipation as well as sturdiness. There are many standardized case designs, but keep in mind that the actual circuit inside can be far different between two ballasts that look the same externally.
All high-quality ballasts are fully waterproofed in a process known as potting, where an epoxy material is poured into the ballast and fills all circuits. The potting material is not cheap, so the least expensive ballasts won’t be potted at all, and low-cost ones might only have a single layer of potting covering the components. The best ballasts are fully potted.
Although all ballasts will fulfill the basic role of controlling power to an HID bulb, some ballasts have been designed with special features to improve performance.
CANBUS: When a ballast is called “CANBUS,” it simply means that it has a module inline on the input signal, which smooths the power input and provides resistance. Some vehicles do not need this at all, when there is a constant input power signal and no CANBUS system. However, it won’t hurt to use it in any vehicle, as it can help provide more reliable operation to any application.
Hot Restrike Protection: When an HID ballast warms up a bulb, it delivers a high amount of power, then lowers it as the bulb warms up to normal operation. If an HID bulb has been running, the bulb already has low reistance since it’s already hot. If the ballast is turned off then back on quickly, it would deliver too much power right away, since the bulb is still hot. This will decrease bulb lifespan, as the electrodes in the bulb are worn down when this happens. To prevent this, high-quality ballasts check to see whether the bulb is hot or not before delivering power, to prevent damage.
EMI Shielding: High-voltage signals produce electrical interference, known as EMI. EMI can interfere with your radio and keyfob. This can be prevented by the use of shielded wires and components in the ballast itself. Additionally, ferrite beads can be used, like you might see on your laptop charging cable, as they absorb interference.
Input Power Range: Due to the way electronics work, most HID ballasts can use input power in a range, such as 9-32V. This is simply due to the components in the device. Of course, in an automotive application, you’ll be using the ballasts normally at around 13V. Just because a ballast can operate at 9-32V instead of 9-24V doesn’t make it any better, so watch out for sellers that promote “32V” HID kits as a selling point. You’re going to be using it around 12V, so that’s all that matters!