DISCRETE MATHEMATICAL TECHNIQUES IN THE ANALYSIS AND ADJUSTMENT 
OF HYBRID NETWORKS 
I.Colomina 
Institut Cartogràfic de Catalunya 
Spain 
ABSTRACT: 
Over the past decade, adjustment of hybrid networks —usually referred to as combined adjustment within 
the photogrammetric comunity— have deserved the attention of numerous researchers. In the software, when 
dealing with the heterogeneous data of hybrid networks, everything tends to be more complex. The paper 
shows how discrete techniques can help deal with this complexity. Two examples are discussed: the detection 
of a family of gross errors and the numbering of unknowns for fill-in reduction. The concept of discrete models 
for the network and standardized discrete kernels for the software are proposed. 
KEY WORDS: discrete models, discrete techniques, graphs, matroids, graph filtering, hybrid networks. 
1 INTRODUCTION 
Over the past decade, hybrid networks have deserved 
the attention of numerous researchers. This is wit- 
nessed by the one time period 1984-1988 of WG 
III/1 (Working Group III/1: Accuracy Aspects of 
Combined Point Determination) of the ISPRS, the 
two time periods 1983-1987, 1987-1991 of SSG 1.73 
(Special Study Group 1.73: Integrated Geodesy) of 
the IAG, and by the meetings organized, either sep- 
arately or jointly, by the two organizations. Today, 
integrated geodesy and combined point determina- 
tion are still active research fields [5]. (The trend 
towards combined approaches in geodesy and pho- 
togrammetry has been mainly influenced by three fac- 
tors: the advent of satellite geodesy —in particular 
the Global Positioning System—, the development of 
comprehensive models inciuding all type of data, and 
the availability of high-speed large-capacity comput- 
ers [9].) 
In general, combined solutions are expected to pro- 
vide more accurate and reliable results. Not less im- 
portant is that global approaches lead to a cost re- 
duction in software development, maintenance and 
acquisition; that they promote closer collaboration 
and understanding between groups traditionally in- 
volved —as well as traditionally separated— in point 
determination tasks; and that, as a result, they in- 
troduce factors of rationality and coherence in the 
corresponding point determination projects. 
The combined adjustment philosophy, however, has 
found small acceptance in practice. 
In conventional adjustment problems, in the first 
step, the unknowns and their accuracy are deter- 
mined. In the second step, it is common to detect 
poorly measured data subsets which can impair the 
quality of the global adjustment. When dealing with 
heterogeneous data sets everything tends to be more 
complex and even the first step may not be easy to 
614 
carry out. Thus, for day-to-day practical projects, the 
magnitude and structure of system equations which 
result from the above general approaches may be 
brought up as an argument against their application. 
Indeed, this is not the point if a suitable numbering 
for the unknowns is computed. 
The heyday of research and development in num- 
bering of graphs associated to geodetic networks was 
the decade of the seventies and the early eighties. In 
addition to the availability of the obtained results,! 
the increasing computer capacity has contributed to 
some decay of the topic. 
In combined networks, however, there are patho- 
logical structures which perturbate the regularity and 
locality that classical photogrammetric and geodetic 
networks have exhibited so far (Section 5). In order 
to apply the old good algorithms, those structures 
must be understood and characterized so they can be 
detected and eliminated. For that purpose, discrete 
mathematics seem to be the best tool. 
Discrete techniques can also contribute to the 
structural analysis of networks, hybrid or not (see 
the related work in [7, 14]). These techniques, have 
already been [implicitely| used for the generation of 
initial approximations in the nonlinear cases and, in 
a much lesser extent, for the detection of what is 
known as gross errors. For instance, many times 
  
l'Three statements describe the situation well. 
First, the rigorous solution of the problem is NP-complete. 
Secondly, there are many algorithms which perform well — 
even at best— under certain regularity conditions. Last, the 
problem has been somewhat closed since it has been proven 
that problems not satisfying those regularity conditions are 
not amenable to sparse gaussian elimination. 
In what photogrammmetric and geodetic netwroks is con- 
cerned, the pure numbering policy —that is, abstract time 
and space complexity considerations— can be summarized as 
follows: if the network is medium-sized (up to 2000—3000 un- 
known groups or even less) use a sequential numbering algo- 
rithm, otherwise use nested dissection; and, of course, try to 
take advantage of any regular pattern which might occur (for 
instance in photogrammetric blocks). 
0 N MS Q N e+ 
q 
ti