An aerial photograph of Longhurst and Knight's Stream Park, new housing developments in Halswell.
A private driveway in Halswell Junction Road with cracking in the concrete.
A photograph of young people skateboarding over road cones and uneven ground at the corner of Sabys Road and Trices Road in Halswell.
A footpath in Halswell where the pavement has cracked and uplifted due to liquefaction.
A photograph of earthquake damage near the corner of Sabys Road and Trices Road in Halswell.
An aerial photograph of Longhurst and Knight's Stream Park, new housing developments in Halswell. Labels have been added to the photograph by BeckerFraserPhotos.
Cracks along the edge of Halswell Road. The footpath has slumped towards the creek on the left due to liquefaction, causing the crack in the road.
Road cones along the side of Halswell Road where the road has been repaired and sealed after slumping. There are still cracks in the footpath and curb.
A private driveway off Halswell Road with extensive cracking. The driveway has slumped into the creek due to liquefaction from the earthquake.
A photograph of cracks in the brickwork of a bridge at the corner of Sabys Road and Trices Road in Halswell.
Photo of liquefaction, Sabys Road, Halswell, taken by John Weeber.
A collapsed brick wall on Halswell Junction Road. A stack of bricks have been saved by the tree which has grown in a curve and is resting on the wall, holding the bricks in place. A pile of bricks can be seen on the ground where they fell.
A photograph of the severe damage to Cashmere Road in Halswell caused by the 4 September 2010 earthquake.
A photograph of the severe damage to Cashmere Road in Halswell caused by the 4 September 2010 earthquake.
A photograph of the severe damage to Cashmere Road in Halswell caused by the 4 September 2010 earthquake.
A photograph of people inspecting the damage to Cashmere Road in Halswell caused by the 4 September 2010 earthquake.
A photograph of people inspecting the damage to Cashmere Road in Halswell caused by the 4 September 2010 earthquake.
Photograph captioned by Fairfax, "Halswell residents Tom Taylor of Halswell Junction Road and Colleen Bennett, showing quake damage to Colleen's place at 37 Kennedys Bush Road".
Photograph captioned by Fairfax, "Halswell residents Tom Taylor of Halswell Junction Road and Colleen Bennett, showing quake damage to Colleen's place at 37 Kennedys Bush Road".
Photograph captioned by Fairfax, "Halswell residents Tom Taylor of Halswell Junction Road and Colleen Bennett, showing quake damage to Colleen's place at 37 Kennedys Bush Road".
Photograph captioned by Fairfax, "Halswell residents Tom Taylor of Halswell Junction Road and Colleen Bennett, showing quake damage to Colleen's place at 37 Kennedys Bush Road".
A photograph of flowers in a road cone. The photograph is captioned by BeckerFraserPhotos, "Halswell Junction Road".
A of flowers in a road cone. The photograph is photograph captioned by BeckerFraserPhotos, "Halswell Junction Road".
A photograph of damage to the Linfox building on Halswell Junction Road.
A photograph of damage to the Linfox building on Halswell Junction Road.
A photograph of damage to the Linfox building on Halswell Junction Road.
A photograph of damage to the Linfox building on Halswell Junction Road.
Photograph captioned by Fairfax, "Cracking up. Roads throughout Halswell were fractured making driving a hazardous and slow process".
Photograph captioned by Fairfax, "Christchurch Earthquake. University student Sam Johnson organised through Facebook students to go into the suburbs to help residents clean up after Saturday morning's earthquake. They gathered in Halswell to help residents clean up the silt from their properties. James Litchwark (L) and James Wigzell shovel dirt from 2A Larsons Road, Halswell".
Land cover change information in urban areas supports decision makers in dealing with public policy planning and resource management. Remote sensing has been demonstrated as an efficient and accurate way to monitor land cover change over large extents. The Canterbury Earthquake Sequence (CES) caused massive damage in Christchurch, New Zealand and resulted in significant land cover change over a short time period. This study combined two types of remote sensing data, aerial imagery (RGB) and LiDAR, as the basis for quantifying land cover change in Christchurch between 2011 – 2015, a period corresponding to the five years immediately following the 22 February 2011 earthquake, which was part of the CES. An object based image analysis (OBIA) approach was adopted to classify the aerial imagery and LiDAR data into seven land cover types (bare land, building, grass, shadow, tree and water). The OBIA approach consisted of two steps, image segmentation and object classification. For the first step, this study used multi-level segmentation to better segment objects. For the second step, the random forest (RF) classifier was used to assign a land cover type to each object defined by the segmentation. Overall classification accuracies for 2011 and 2015 were 94.0% and 94.32%, respectively. Based on the classification result, land cover changes between 2011 and 2015 were then analysed. Significant increases were found in road and tree cover, while the land cover types that decreased were bare land, grass, roof, water. To better understand the reasons for those changes, land cover transitions were calculated. Canopy growth, seasonal differences and forest plantation establishment were the main reasons for tree cover increase. Redevelopment after the earthquake was the main reason for road area growth. By comparing the spatial distribution of these transitions, this study also identified Halswell and Wigram as the fastest developing suburbs in Christchurch. These results provided quantitative information for the effects of CES, with respect to land cover change. They allow for a better understanding for the current land cover status of Christchurch. Among those land cover changes, the significant increase in tree cover aroused particularly interest as urban forests benefit citizens via ecosystem services, including health, social, economic, and environmental benefits. Therefore, this study firstly calculated the percentages of tree cover in Christchurch’s fifteen wards in order to provide a general idea of tree cover change in the city extent. Following this, an automatic individual tree detection and crown delineation (ITCD) was undertaken to determine the feasibility of automated tree counting. The accuracies of the proposed approach ranged between 56.47% and 92.11% in thirty different sample plots, with an overall accuracy of 75.60%. Such varied accuracies were later found to be caused by the fixed tree detection window size and misclassifications from the land cover classification that affected the boundary of the CHM. Due to the large variability in accuracy, tree counting was not undertaken city-wide for both time periods. However, directions for further study for ITCD in Christchurch could be exploring ITCD approaches with variable window size or optimizing the classification approach to focus more on producing highly accurate CHMs.