LSU 4.9 is superior to LSU 4.2.

The major difference between LSU 4.9 and 4.2 is that LSU 4.9 uses the reference pumping-current, while LSU 4.2 uses the reference air. What does this mean? Let’s read this true story from the auto industries: when Bosch first designed a wideband oxygen sensor, a reference air cell was used to provide a reference of stoic AFR.

The technology was to keep the pumping cell balanced with the reference air cell, by pumping the oxygen out of the pumping cell. The pumping current was the indication of the actual AFR in the exhaust gas. The bigger the pumping current, the more the oxygen in the exhaust, and vice versa. Therefore the reference air was vital to the accuracy of the sensor, because it was THE reference. It worked well in the lab, but not so good in the real life, because the environment around the sensor on a car was much worse. The reference air cell was susceptible to be contaminated by the exhaust gas, and / or other surrounding pollutions. Once the reference air was contaminated, the whole characteristics of the sensor were shifted to the low side. It was called “Characteristic Shifted Down”, or CSD, in the industries. This was the biggest problem of LSU 4.2 that was used in some early OEM applications. And it caused the big quality issue to Bosch. To fix this problem, Bosch redesigned the LSU sensor, and came up with LSU 4.9 version. LSU 4.9 sensor completely got rid of the reference air. Instead, it used a reference pumping current which was equivalent to the stoic reference air, but without having any physical air in the cell. So the technology became: the actual pumping current was compared to the reference pumping current to maintain the balance. The actual pumping current was still the indication of the actaul AFR, but the reference was a calibrated electrical signal, and stayed same all the time, all the situations.

This is the fundamental difference between the LSU 4.2 and LSU 4.9.

LSU 4.9 gets rid of the reference air, and therefore gets rid of the biggest failure mode. As a result, LSU 4.9 has a long life and can maintain the accuracy throughout the life. Only since then, Bosch LSU sensors have been used widely in the auto industries.

Nowadays, all OEMs who use Bosch O2 sensors are using LSU 4.9. GM, Ford, and Chrysler all use LSU 4.9 now. If you check out the O2 sensors on your recently bought vehicles, cars/SUVs/Pickups, (since 2007 or later), on the exhaust manifolds, you will find out that they are all exclusively LSU 4.9. No more 4.2 sensors can you find on OEM vehicles.

Most aftermarket wideband controllers are still using LSU 4.2, mainly for low cost reasons. Bosch sells the LSU 4.2 to the aftermarket at a much lower price than LSU 4.9. Plus, many of those companies do not want to or are not able to adapt the new LSU 4.9 sensors. There is a big mis-understanding that LSU 4.9 is only for diesel engines, because it can measure very lean AFRs. That’s not true. There is a diesel version of LSU 4.9, called LSU4.9D, mainly because of fuel and temperature difference. LSU 4.9 has been widely used with the gasoline engines. In fact, it is the most popular gasoline engine O2 sensor now, not only because it measures wide range of AFR, but also because it has the very good reliability, and high accuracy.

There are a few wideband controller companies in the aftermarket using LSU 4.9. But that does not mean all controllers using LSU 4.9 are equal. Even with the same LSU 4.9 sensor, the controller can make a big difference. Some wideband controllers are designed for AFR display only, and they are named as “wideband AFR gauges” instead of controllers. You can imagine that those wideband gauges do not have good accuracy and fast response rate because they are not designed for those purposes. Those gauges are more for good looking than for engine tuning purposes. For engine controls, the accuracy and response rate are the most critical characteristics of a wideband controller. One way to tell whether a wideband controller is good or not, is to see whether it can be used as a feedback device for the ECU. A feedback device must provide a real-time signal in the fast rate and high accuracy, even under dynamic situations. The requirements for a feedback device are much, much more than those for a gauge.

Even with a LSU 4.2, the controller makes a big difference. Bosch sensors are not easy to fail even with a LSU 4.2, if controlled appropriately. Especially, LSU 4.9 is designed for more than 10 year life because it has to, for the vehicle life. It should not fail in short time, like a couple of years. Many OEM cars have been running with LSU 4.9 for years. Why so many aftermarket wideband systems have failed LSU sensors? Because many of them don’t have a good heating control strategy. The number 1 failure mode of a LSU sensor is being heated up too fast or too earlier. O2 sensors are made of ceramic materials, which can be damaged by severe thermal shocks, like condensations, liquid residuals, or just high heating power when it’s still cold. A very careful heating strategy to detect the dew point and a close-loop sensor temperature control are vital for the life of the sensors. That’s why the LSU sensor must be controlled in the context of engine controls. You may say, only those know engine controls can design a good wideband controller.

Furthermore, the accuracy of LSU sensors is highly dependent on the operating temperature of the sensing element. The sensor reading can be very different if the temperature of the sensing element is different. LSU sensors must work at the vicinity of certain temperatures for the good accuracy.

Bosch CJ125 chip is designed for this task. The heating strategy is a close loop control based on the measured sensor temperature. LSU 4.9 has a much higher sensor temperature resolution because of the resistance characteristics, so the heater controls are much better than LSU 4.2. Therefore, 4.9 has a longer life and better accuracy.

In short, not only the sensor LSU 4.9 is superior to 4.2; but also the controller with a CJ125 chip makes it an OE equivalent system.

If you are still not sure, you can use an oscilloscope to actually measure the analog outputs of different wideband controllers if you really want to see the difference. Data do not lie. Don’t forget, when you use a scope, you better set the time scale in 10ms or smaller. If you have a time scale of 100ms or more, then there could be no difference for any controllers.

More info on LSU4.9 vs. LSU4.2

What makes LSU 4.9 superior to LSU 4.2 is not only because LSU 4.9 uses an electrical reference signal, and LSU 4.2 uses the reference air, but also because Bosch significantly improved every aspect of the LSU sensor in the 4.9 version, and made it a mass production level, with superior reliability and quality. Once again, with LSU 4.9, Bosch has dominated the oxygen sensor market in the automotive industry as it did before. Below are some of major improvements of LSU 4.9:

1) Thinner sensing element. All LSU sensors use thick-film technology, which means the whole sensing element is composed of a bunch of thin layers made of different materials. LSU 4.2 has a total thickness of the sensing element as 1.5mm (1 mm = 0.03937 inches), while LSU 4.9 is only half of that. How significant is this? Think about there are about 10 layers of materials in the sensing element, you squeeze them into 1.5mm thickness. Already hard to imagine? then you have to cut it to half for LSU 4.9. This is the most significant reason that why LSU 4.9 is more expensive than LSU 4.2. Because everything that is used to manufacture the LSU 4.2 sensors has to theoretically double the precision to make LSU 4.9! What are the benefits? more accurate measurements and faster response! Even common sense tells you, when the electronics become smaller and smaller, they tend to be more sensitive and respond faster!

2) New design of protection tubes. The sensing element is protected by a double layer tube. LSU 4.9 has a new design of the inner tube. It has a sophisticated structure to create gas rotations around the sensing element, and it also blocks the liquid droplets reaching the sensing element. What are the benefits? improved gas flow, faster dynamic response and significantly reduced thermal shock risk. Especially the latter one, that thermal shock has been the number one enemy of the oxygen sensor all the time. By fixing this problem, Bosch fundamentally made LSU 4.9 sensors to the mass production level for auto industries. In auto industries, all parts must be designed for at least 10 year life. The LSU sensor is the most important emission control device. It must sustain the harsh environment for 10 years or more. Since 2007, many GM, Ford and other OEM vehicles have been equipped with LSU 4.9 sensors to meet the recent stringent emission requirements. Most likely your vehicle has one LSU 4.9 at least, some have 2 or more. And most likely none of them has been broken. Otherwise you will see the check engine light ON on the dash the first thing.
Next time, if your vendor asks you to buy spare LSU sensors with their wideband controller, tell him: I have been driving my truck for 5 years which has a LSU sensor and it is still working fine. Why would I have to plan to change the sensor soon with your controller?

3) Measuring the internal resistance and close loop control of the sensor temperature. This is done with the CJ125 chip. We know the temperature of the LSU sensor has big impact on the accuracy and response speed. In fact, LSU sensor only works well at the vicinity of certain temperature. For LSU 4.9, it is 780 Celsius. Bosch manufacturer calibration and sensor characteristic data are done based on this temperature. If your controller can not maintain the sensor temperature around 780 C, you must compensate it for the difference, which many wideband controller manufactures don’t do. With a CJ125 chip, you can measure the internal resistance of the sensor, which is the direct reflection of the sensor temperature, and use it as the feedback to control the sensor temperature in a close-loop manner. Only by controlling the sensor temperature in the close-loop mode can you make the LSU sensor accurate. Next time, when you buy a wideband controller, ask your vendor: can your controller do close-loop control of the sensor temperature? Can your controller show the real-time sensor temperature so I can see it?

There are many other advantages of LSU 4.9 sensors over 4.2 ones. But not all people are interested in too much technical details. You can use common sense then. Why GM, Ford and other car manufacturers all use LSU 4.9, not LSU 4.2? If LSU 4.2 were very close to 4.9 and it is much cheaper, why wouldn’t they just use 4.2? It would generate a lot more profits. If LSU 4.2 were able to do the same job, why Bosch would even bother to spend a lot of money to develop new ones? In auto industry, ETAS lambda meters are the widely used professional wideband controller. They are used exclusively with LSU 4.9 sensors, though they do support 4.2. But nobody would use an ETAS lambda meter with a LSU 4.2. By the way, ETAS is majority-owned by Bosch.

LSU 4.9 has become a mass production auto part. It is not a luxury part any more. It is available to aftermarket already. Yes, it is more expensive than LSU 4.2, but the benefits of 4.9 worth much more than the price difference. For engine tuning, every bit of the accuracy gain of the sensor can save you tons of hours of tuning time.

Why CJ125?

CJ125 is the ASIC (application specific integrated circuits) designed for LSU sensors by Bosch.

Bosch uses this chip everywhere that the LSU sensor is used in their engine control systems. You can find this chip on almost every Bosch ECU (engine control unit). By the way, Bosch is the largest auto supplier in the world, and especially its ECU. Bosch may have the largest piece of the ECU market in the auto industries. Bosch is known more for its engine management system than for its sensors. Bosch’s ECUs often mean quality and premium prices. Not to flatter Bosch here, it is just widely acknowledged in the industries.

With that being said, CJ125 is the chip that has been evolved from a few generations, just like LSU sensors. People still remember earlier production version of CJ110, which was a good one. CJ125 has got the best practice of Bosch LSU sensor controls from the years. Bosch has developed many ASICs and CJ125 is one of the best they have done.

There are some aftermarket vendors who tend to tout that their wideband controller circuit design is even better than Bosch’s. That needs a lot of substantial proof. It is not absolutely impossible to do better, it is just too expensive and too much efforts to exceed Bosch design, for small companies. In auto industries, the known professional lambda meters are ETAS, and ECM professional products. ETAS uses CJ125 for their lambda meters. ECM is probably the only one that can compete against ETAS in this area. ECM obviously has invested a lot in their meters and those meters are certainly expensive (not their low end ones please).

Why keep talking who use CJ125 instead of what are the advantages of CJ125? because most people simply don’t have the enough background of electronics. The easier way is to use your common sense to tell why CJ125 is an excellent semiconductor part.

Certainly for education purpose, you can design a DIY circuit to control LSU sensors, and show what the principles are for the LSU sensor controls. That is cool, too. But for engine tuners, it is more important to use a superior wideband controller to tune the engine, instead of learning how LSU sensor is controlled by the controller.

Why not many aftermarket vendors use CJ125? One reason is the software that is needed to run the CJ125 is too complicated for many. CJ125 is designed to meet the most stringent OBDII regulations. Many sophisticated circuits are integrated in it, which requires professional embedded software knowledge and skills to master it.

A little more on ALM

Besides air/fuel ratio measurement, ALM provides some supplemental functions which make your measurement or tuning more convenient: linear analog output to your ECU or gauge; LED digital display; engine RPM probe, other analog sensor inputs like MAP and/or exhaust gas temperature (EGT); data logging with a serial communication to a PC, etc