The Hyundai Tucson has long been a popular choice for those desiring the functionality of a crossover SUV at a reasonable price. Making the case even stronger now is an expanded list of Tucson offerings highlighted by plug-in hybrid and enthusiast-oriented N Line models that have joined the line’s gas-powered and electric hybrid variants.
Conventionally-powered Tucsons are equipped with a 2.5-liter engine delivering 180 hp and 195 lb-ft torque, delivering 26 city/33 highway mpg. PHEV and hybrid Tucson models share a 1.6-liter, turbocharged and direct-injected inline four-cylinder gas engine. These are equipped with Hyundai’s Continuously Variable Valve Duration technology that optimizes valve opening duration to improve power, efficiency, and emissions. The hybrid gets a 59 horsepower electric motor and 1.5 kWh lithium-ion battery that brings 226 total system horsepower and up to 38 city/38 highway mpg.
With the addition of the plug-in hybrid’s 90 hp electric motor and a larger 13.8 kWh lithium-ion battery, total system horsepower increases to 261 hp and 258 lb-ft torque. EPA rates the Tucson PHEV’s electric-only range at 33 miles and fuel economy at 80 MPGe, with a 35 mpg combined city/highway mpg rating running on gasoline. Hyundai says the model’s onboard 7.2 kW charger will allow charging the battery in less than two hours when connected to a 220-volt Level 2 charger.
The remainder of the Tucson PHEV’s drivetrain consists of a six-speed automatic transmission with steering wheel-mounted paddle shifters and a standard HTRAC AWD system with selectable drive modes. All Tucson models, including the PHEV, have a maximum tow rating of 2,000 pounds. The PHEV’s curb weight is a few hundred pounds higher than the conventional and hybrid models, so its payload capacity is commensurately less, rated at 1,012 pounds for SEL models and 1,166 pounds for Limited versions.
A higher level of driving dynamics is delivered to match the Tucson’s sporty new exterior design. The AWD PHEV and hybrid models are built with Hyundai’s e-handling technology that, under certain road conditions and driving inputs, applies an incremental amount of electric motor torque to the wheels. This enables the e-handling system to affect vehicle weight transfer – and therefore the tire’s contact patch – to improve cornering.
Tucson models are equipped with a number of safety technologies as part of Hyundai’s SmartSense Safety Feature suite. Standard safety features on both the SEL and Limited models of the Tucson PHEV include Forward Collision-Avoidance Assist, Blind-Spot Collision-Avoidance Assist, Lane-Keeping Assist, Driver-Attention Warning, and Rear Cross-Traffic Collision-Avoidance Assist. Limited models add such features as blind-view and surround-view monitors and Remote Smart Parking Assist.
The Tucson PHEV’s interior amenities vary depending on model. Both SEL and Limited are equipped with Apple CarPlay and Android Auto capabilities and have USB charging points for front and rear passengers. Stepping up to the Limited adds a 10.25-inch digital instrument cluster and 10.25-inch color touchscreen (SEL has an 8-inch screen), a Bose premium sound system, and wireless device charging.
Prices start at $25,800 for the standard 2.5-liter powered Tucson with the hybrid coming in at $29,750 and the plug-in hybrid $35,400.
There was a time when sophisticated driver assist systems were the realm of luxury cars. The reason is simple, really. The cost of any new tech innovation is high, and it’s easiest to bury this cost in higher end vehicles offered at a premium price. It was thus with many innovations we now take for granted in our cars like air bags and anti-lock braking. These days, the most desired driver assist and advanced safety systems are pretty much standard fare in most new models.
We were impressed years ago when Honda launched its ‘Safety for Everyone’ program and made its latest safety innovations standard fare on all its vehicles. The auto industry as a whole has followed suit, and now even the most sophisticated systems can be found on entry-level models, increasingly as standard equipment or as available options. While drivers of premium vehicles may still be the first to experience the latest new twist operating silently behind the scenes as they drive, you can be assured the technology will filter down to all models over time.
There are reasons for that because safety is always on the minds of new car buyers. The availability of systems that keep drivers and their families safe on the road, or at least as safe as possible, are highly desired. Automakers know this. Active and passive safety offer a competitive advantage in new car sales, right alongside other traditional touchstones like value, style, dependability, efficiency, and performance. If a new and highly-desired feature is introduced by one brand’s vehicles, there’s no doubt you will be seeing it offered in competitive models soon enough. There’s too much at stake for automakers not to emphasize safety, just as they emphasize electrification, efficiency, and environmental performance in their new model vehicles.
These days, technology is an active participant in our driving experience, constantly looking to warn us of unsafe conditions and offer alerts, and sometimes even initiate last-minute control to avoid an imminent collision. Their importance can’t be overstated. In the early years of driver assist systems, there were claims and assumptions regarding their promise for preventing potential collisions and saving lives. Now there is actual data to support this.
Recently, GM partnered with the University of Michigan Transportation Research Institute to study the real-world effect its driver assist, active safety, and advanced headlight features were having in preventing or lessening various types of crashes. The study involved data from some 3.7 million GM vehicles across 20 models, making use of police crash report databases from 10 states. Comparisons were made involving vehicles equipped with advanced active safety features and others without this functionality.
The results showed that driver assist systems can make a dramatic difference in eliminating or mitigating crashes. Automatic emergency braking with forward collision alert was shown to reduce rear-end striking crashes by 46 percent. Lane keep assist with lane departure warning reduced lane departure crashes by 20 percent, with lane change alert and side blind zone alert bringing a reduction of 26 percent in lane change crashes.
Even advanced lighting made a difference in driving safety. Here, high-intensity discharge headlights brought a 21 percent reduction in nighttime crashes involving pedestrians, bicyclists, or animals. In addition, advanced headlight systems that automatically turn high beams on or off in response to surrounding conditions delivered a 35 percent reduction. When combined, the two lighting systems resulted in a 49 percent crash reduction.
Clearly, automobiles have become more complex over time. In their early years, an automobile’s electrical system was limited to fundamental functions like a starter, generator, headlights and taillights, instrumentation, and an audio system. Over the years this grew more extensive, including everything from navigation, electric-assist steering and braking, electronic transmission control, electronic ignition, anti-lock braking, an array of airbags, and advanced emissions controls.
Today’s more sophisticated automobile integrates all this and more, from active safety assist systems and real-time traffic navigation to semi-autonomous driving, all enabled by on-board computers. Industry experts point out that today’s vehicles are often equipped with hundreds of controllers and sensors, and dozens of on-board computers (electronic control units, or ECUs), generating tens of gigabytes of data every hour. It’s expected that the coming generation of fully autonomous vehicles could generate upwards of 30 terabytes every day.
Supporting the electronics that process, analyze, and activate, the array of cameras, radar, and LIDAR sensors strategically and discretely positioned around a connected car ‘see’ vehicles, objects, and people ahead, around, and behind. These feed information to on-board systems that enable everything from the view seen in a back-up camera to determining the speed of a car in front of you, allowing adaptive cruise control to adjust your speed to avoid overtaking the vehicle ahead.
These sensors are constantly evolving and improving, a necessity as we head toward fully-autonomous driving. While LIDAR continues to be a favored system by automakers, other innovations are in the works. One example is next-generation radar systems. Until now, vehicle radar has been limited to capturing just speed and direction, which is one of the reasons why vehicles use multiple sensor types for their driver assist and semi-autonomous driving features. Now, the newest long-range radar designs will determine an object’s speed, range, direction, and elevation, even at higher speeds and under challenging lighting or weather conditions.
Evolution is a hallmark of life, and it seems, of driving. Even as our cars are getting more complex in every sense as they adapt to modern life, they are also getting smarter…and safer. All that technology is delivering much more than the comfort, performance, entertainment, and driving pleasure we’ve come to expect from modern vehicles over time. We now benefit from a more confident driving experience and enhanced safety on the road as well, with technologies like those described below serving as our copilot.
ADAPTIVE CRUISE CONTROL: As a stand-alone system or as part of semi-autonomous driving systems, ACC works like conventional cruise control with the addition of sensing technology that determines the speed and distance of the car ahead. It modifies your set cruise speed to avoid overtaking that vehicle. Many systems can bring your vehicle to a full stop if needed. Some advanced systems even reference map data to anticipate upcoming curves, roundabouts, toll booths, and more, then automatically reduce speed accordingly.
AUTOMATIC EMERGENCY BRAKING: Coupled with advance warning of unsafe closing speed or other immediate hazards, this system will automatically apply emergency braking to help avoid or mitigate a collision. Rear and pedestrian AEB is also offered as part of this system.
AUTONOMOUS DRIVING: Sometimes confused with fully ‘self-driving’ capabilities not yet here or approved, to degrees, today’s semi-autonomous systems can help keep a vehicle centered in its lane, pace a vehicle ahead at a safe distance, and often bring your vehicle to a full stop in gridlocked traffic, then resume driving when traffic in your lane is moving again. Some systems identify the pressure of hands on the steering wheel to allow continuing use of a semi-autonomous driving system, while others, like Cadillac, use a strategically-mounted camera that monitors a driver to confirm they are paying attention to the road ahead.
BLIND SPOT MONITORING: This system alerts a driver of vehicles in its blind spots to increase safety when changing lanes, passing, or being passed.
FORWARD COLLISION WARNING: Audible and visual warnings are provided to alert a driver of the potential of a forward collision. Some systems also provide brake pulsing as a further warning to gain a driver’s immediate attention.
HEAD-UP DISPLAY: A HUD projects driving information projected ahead of a driver’s view, sometimes as simple as mph but often providing info on various driver assist functions including turn-by-turn navigation.
LANE DEPARTURE WARNING: This system provides audible and visual warnings if your vehicle strays outside of its lane when a turn signal is not activated.
LANE KEEP ASSIST: Taking over after a lane departure warning, this function provides varying degrees of steering input to help maintain lane position.
NIGHT VISION: Using infrared sensing technology, night vision displays an enhanced view of the road ahead that helps identify pedestrians, animals, or other hazards that may be beyond the view of a car’s headlights.
PARK ASSIST: This system enables a driver to select automated parallel, and sometimes perpendicular, parking functionality. It uses sensors to identify an open parking space of suitable size and the position of parked vehicles, then controls steering angle to automatically guide your vehicle into the space. Many systems require a driver to control braking, acceleration, and gear position, while others handle all functions automatically.
REAL-TIME TRAFFIC: Navigation systems that integrate real-time traffic information are valuable in saving time, fuel, and maximizing driving range with their ability to reroute around traffic jams and construction projects.
REAR BACK-UP CAMERA: Now found on a wide range of vehicles, a view to the rear is shown in a dashboard display or rear-view mirror when a driver shifts into reverse, often including grid lines depicting a driver’s angle of approach and relative distance from nearby vehicles or objects. Audible warnings are provided when objects are too close or a potential collision with an object, vehicle, or pedestrian is detected.
REAR PARK ASSIST: At low speed while in reverse, sensors detect objects and a potential collision, providing a warning brake pulse and then bringing your vehicle to a stop.
SURROUND VIEW CAMERA: This technology uses multiple cameras strategically positioned on a vehicle to provide a ‘birds’-eye’ perspective of the vehicle and its immediate surroundings.
The third-generation Nissan Versa is 2.3 inches lower, 1.8 inches wider, and 1.6 inches longer than the Versa it replaces and styling is definitely more handsome. It is available in S, SV and SR levels. With prices starting at $14,730 and fully loaded SRs coming in under $20,000, the Nissan Versa represents great value.
All Nissan Versas continue to be powered by the same 1.6-liter, four-cylinder DOHC engine with Continuously Variable Valve Timing Control System (CVTCS) as used in the outgoing model. However, it is a bit more powerful this year with 122 horsepower and 114 lb-ft torque. A five-speed manual continues to be the standard transmission for the S grade, while the SV and SR trims only come with an Xtronic CVT (Continuously Variable Transmission). The CVT is optional on the base S trim. Manual gearbox-equipped 2020 Versas get 27 city/40 highway mpg while CVT versions net 32 city/40 highway mpg.
The S, SV, and SR each offer a slightly difference appearance beyond their 15-, 16- and 17-inch wheels, respectively, with the upper two alloys. Headlights on the S and SV are halogen, while the SR has LEDS. Interiors also get better as you go up in trim levels. SV and SR trims feature a 7-inch touchscreen compatible with Apple CarPlay and Android Auto. These trims also get a 7-inch instrument cluster. S trims get a 7-inch display, but without the Nissan Connect infotainment system or Apple CarPlay and Android Auto compatibility. All trims have three USB ports, pushbutton start, and Bluetooth for calls and audio streaming.
Even at these budget prices, the Versa has many driver-assist aides. All trims get standard Automatic Emergency Braking with Pedestrian Detection, Rear Automatic Braking, and Lane Departure Warning. SV and SR trims add Blind Spot Warning, Intelligent Driver Alertness, and Rear Cross Traffic Alert. Cruise control is standard on all trims. However, Intelligent Cruise Control that maintains a set distance to the vehicle ahead is only optional on the top SR trim. All trims get auto on/off headlights and high-beam assist.
Nissan strives to ensure a driver never leaves a child in a Versa SV or SR with the model’s standard Rear Seat Alert system, which reminds drivers to check the back seat when exiting by sounding the Versa’s horn.
We are heading toward self-driving cars quicker than anyone could have imagined just a few years ago. While it will clearly be some time before our highways are packed with driverless cars making their way to work, home, and parts beyond, there are glimpses of the future driving alongside us now.
It may be the Honda Civic self-aligned in the fast lane beside you, or the Ford Fusion Energi in your rear view mirror that stopped without driver assistance as traffic ground to a halt, then automatically paced your car as your lane began moving again. Or maybe the driver of the nearby Subaru Crosstrek Hybrid who misjudged how quickly traffic would stop, but escaped incident because of on-board systems that sensed a collision and automatically initiated emergency braking. And what about that Tesla Model S ahead that signaled and changed lanes seemingly on its own as its driver focused on something else?
These are real capabilities of vehicles on the road today. Not all models with autonomous technologies are ‘green’ cars, but assuredly many of them will be since there’s a natural convergence of autonomous driving technology and more efficient cars unfolding before us. This is only gathering momentum as a growing number of vehicles begin to feature systems like these.
Already, cars are increasingly equipped with an array of sensors, radar, and cameras to facilitate driver assistance systems that help deal with mundane chores like backing up safely and parallel parking. These same sensors and systems provide a foundation for even more sophisticated autonomous driving capabilities.
Several automakers are striving mightily to lead the field. Tesla is one of these, not only with the ability for its Model S to autonomously stay in its lane and with traffic flow, but automatically and safely change lanes with the flick of a turn signal when Autosteer is engaged. Cadillac is another with its upcoming Super Cruise.
Volvo is also at the forefront of this race to an autonomous driving future, in part because autonomous cars are considered much safer ‘drivers’ than humans and this aligns well with Volvo’s ambitious goal to eliminate traffic fatalities in its vehicles by 2020. Its XC90 plug-in hybrid already features some of the most advanced autonomous systems out there including Sensus Connect, Intersection Auto Brake, and Pilot Assist. Volvo has also created its Concept 26 autonomous driving interior for the XC90, the first such autonomous-focused concept interior built on a vehicle platform sold today. Volvo is taking a lead role in the world’s first large-scale autonomous driving pilot project that will find 100 self-driving Volvos negotiating everyday driving tasks on 30 miles of public roads around Gothenburg, Sweden.
The specter of life with self-driving cars presents its challenges, not the least of which is consumer distrust of such systems and the concern we will lose the driving enjoyment and sense of freedom that automobiles have brought us since their invention. While we may be in a new era that finds technology impacting most facets of daily life – with this technology increasingly making its way to our cars – the love of driving remains a priority for many.
This is supported by a recent Volvo survey in which a vast majority of those asked said autonomous car technology should respect the love of driving and, in fact, autonomous cars should include a steering wheel even if they are capable of driving themselves. At the same time, most felt that technology in autonomous cars would make their travel time more productive. In other words, we want these worlds to coexist. There’s a lot to read into that …perhaps from the driver’s seat at 65 mph, no?
Chevrolet’s all-new 2016 Malibu features an aggressively-stylish design, loads of on-board tech, a four inch longer wheelbase, and greater rear leg room. It does all this while also increasing efficiency compared to its predecessor. The bump in efficiency comes in no small part from the use of a high strength steel structure that sheds 300 pounds, greater use of aluminum, a lighter engine, and lighter accessories.
Upping the efficiency ante is Chevy's Malibu Hybrid variant, which was distinguished at this year's Washington Auto Show as Green Car Journal's 2016 Connected Green Car of the Year™. The Malibu Hybrid won over finalists that included the Audi A3 e-tron, BMW 330e, Toyota Prius, and Volvo XC90 T8.
This model's hybrid tech is packaged so discretely there’s virtually no differentiation from a conventionally powered 2016 Malibu. Power is delivered by a 1.8-liter direct-injected four-cylinder engine mated to a two-motor drive unit, providing 182 total system horsepower. The drive unit, which is slightly modified from the 2016 Chevrolet Volt powertrain and integrates propulsion and generating motors, kicks in at higher speeds and high loads to provide additional power for acceleration. Since it’s not a plug-in, the Malibu Hybrid has a significantly smaller 1.5 kilowatt-hour lithium-ion battery pack compared to the Volt's 18.4 kilowatt-hour pack. This enables efficient hybrid operation plus a nominal mile or so of all-electric driving at speeds up to 55 mph.
Efficiency is impressive with the Malibu Hybrid achieving an EPA rated 47 mpg in city driving and 46 mpg on the highway. The conventionally powered 1.5-liter turbocharged four-cylinder version of the Malibu nets 27 mpg city and 37 mpg highway fuel efficiency, with the 2.0-liter turbo variant achieving 22 mpg in the city and 33 mpg on the highway.
The Malibu Hybrid also shares the Volt’s blended regenerative braking system, which provides maximum kinetic energy recovery during braking to generate electricity stored in the battery pack for maintaining charge. The engine features Chevrolet’s first application of Exhaust Gas Heat Recovery (EGHR), technology that uses exhaust heat to warm the engine and cabin. EGHR improves engine warm-up and ensures consistent fuel economy performance in cold weather.
Advanced on-board electronics and connectivity are hallmarks of the new Malibu Hybrid. The mid-size sedan comes standard with Chevrolet MyLink Radio and an 8-inch diagonal color touch screen, Apple CarPlay and Android Auto compatibility, rear vision camera, OnStar, and 4G LTE with a built-in Wi-Fi hotspot. That’s a lot of tech for a model that starts at an approachable $28,645 with much more highly desired technology available.
The Malibu features front pedestrian braking, low speed front automatic braking, and parking assist. When activated, adaptive cruise control maintains a set speed while also adjusting speed to keep you a safe distance from cars ahead. Selecting lane keep assist automatically provides steering input to help keep you from drifting from your lane unless a turn signal is activated,
Parents will appreciate Teen Driver, which encourages safe driving by muting the audio of any device paired with the vehicle when front-seat occupants aren't wearing seat belts. It is also the first in-vehicle system in the industry that lets parents view stored information on how their teenagers drove the vehicle, which can be a useful teaching tool for young drivers.
